2019-01-31 12:06:23 +08:00
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.. _memory_allocation:
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2018-11-20 00:00:49 +08:00
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2018-09-14 17:27:58 +08:00
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=======================
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Memory Allocation Guide
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=======================
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Linux provides a variety of APIs for memory allocation. You can
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allocate small chunks using `kmalloc` or `kmem_cache_alloc` families,
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large virtually contiguous areas using `vmalloc` and its derivatives,
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or you can directly request pages from the page allocator with
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`alloc_pages`. It is also possible to use more specialized allocators,
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for instance `cma_alloc` or `zs_malloc`.
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Most of the memory allocation APIs use GFP flags to express how that
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memory should be allocated. The GFP acronym stands for "get free
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pages", the underlying memory allocation function.
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Diversity of the allocation APIs combined with the numerous GFP flags
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makes the question "How should I allocate memory?" not that easy to
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answer, although very likely you should use
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::
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kzalloc(<size>, GFP_KERNEL);
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Of course there are cases when other allocation APIs and different GFP
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flags must be used.
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Get Free Page flags
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===================
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The GFP flags control the allocators behavior. They tell what memory
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zones can be used, how hard the allocator should try to find free
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memory, whether the memory can be accessed by the userspace etc. The
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:ref:`Documentation/core-api/mm-api.rst <mm-api-gfp-flags>` provides
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reference documentation for the GFP flags and their combinations and
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here we briefly outline their recommended usage:
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* Most of the time ``GFP_KERNEL`` is what you need. Memory for the
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kernel data structures, DMAable memory, inode cache, all these and
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many other allocations types can use ``GFP_KERNEL``. Note, that
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using ``GFP_KERNEL`` implies ``GFP_RECLAIM``, which means that
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direct reclaim may be triggered under memory pressure; the calling
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context must be allowed to sleep.
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* If the allocation is performed from an atomic context, e.g interrupt
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handler, use ``GFP_NOWAIT``. This flag prevents direct reclaim and
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IO or filesystem operations. Consequently, under memory pressure
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``GFP_NOWAIT`` allocation is likely to fail. Allocations which
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have a reasonable fallback should be using ``GFP_NOWARN``.
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* If you think that accessing memory reserves is justified and the kernel
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will be stressed unless allocation succeeds, you may use ``GFP_ATOMIC``.
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* Untrusted allocations triggered from userspace should be a subject
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of kmem accounting and must have ``__GFP_ACCOUNT`` bit set. There
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is the handy ``GFP_KERNEL_ACCOUNT`` shortcut for ``GFP_KERNEL``
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allocations that should be accounted.
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* Userspace allocations should use either of the ``GFP_USER``,
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``GFP_HIGHUSER`` or ``GFP_HIGHUSER_MOVABLE`` flags. The longer
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the flag name the less restrictive it is.
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``GFP_HIGHUSER_MOVABLE`` does not require that allocated memory
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will be directly accessible by the kernel and implies that the
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data is movable.
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``GFP_HIGHUSER`` means that the allocated memory is not movable,
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but it is not required to be directly accessible by the kernel. An
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example may be a hardware allocation that maps data directly into
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userspace but has no addressing limitations.
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``GFP_USER`` means that the allocated memory is not movable and it
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must be directly accessible by the kernel.
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You may notice that quite a few allocations in the existing code
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specify ``GFP_NOIO`` or ``GFP_NOFS``. Historically, they were used to
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prevent recursion deadlocks caused by direct memory reclaim calling
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back into the FS or IO paths and blocking on already held
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resources. Since 4.12 the preferred way to address this issue is to
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use new scope APIs described in
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:ref:`Documentation/core-api/gfp_mask-from-fs-io.rst <gfp_mask_from_fs_io>`.
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Other legacy GFP flags are ``GFP_DMA`` and ``GFP_DMA32``. They are
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used to ensure that the allocated memory is accessible by hardware
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with limited addressing capabilities. So unless you are writing a
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driver for a device with such restrictions, avoid using these flags.
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And even with hardware with restrictions it is preferable to use
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`dma_alloc*` APIs.
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2020-07-19 23:36:41 +08:00
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GFP flags and reclaim behavior
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------------------------------
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Memory allocations may trigger direct or background reclaim and it is
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useful to understand how hard the page allocator will try to satisfy that
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or another request.
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* ``GFP_KERNEL & ~__GFP_RECLAIM`` - optimistic allocation without _any_
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attempt to free memory at all. The most light weight mode which even
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doesn't kick the background reclaim. Should be used carefully because it
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might deplete the memory and the next user might hit the more aggressive
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reclaim.
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* ``GFP_KERNEL & ~__GFP_DIRECT_RECLAIM`` (or ``GFP_NOWAIT``)- optimistic
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allocation without any attempt to free memory from the current
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context but can wake kswapd to reclaim memory if the zone is below
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the low watermark. Can be used from either atomic contexts or when
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the request is a performance optimization and there is another
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fallback for a slow path.
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* ``(GFP_KERNEL|__GFP_HIGH) & ~__GFP_DIRECT_RECLAIM`` (aka ``GFP_ATOMIC``) -
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non sleeping allocation with an expensive fallback so it can access
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some portion of memory reserves. Usually used from interrupt/bottom-half
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context with an expensive slow path fallback.
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* ``GFP_KERNEL`` - both background and direct reclaim are allowed and the
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**default** page allocator behavior is used. That means that not costly
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allocation requests are basically no-fail but there is no guarantee of
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that behavior so failures have to be checked properly by callers
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(e.g. OOM killer victim is allowed to fail currently).
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* ``GFP_KERNEL | __GFP_NORETRY`` - overrides the default allocator behavior
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and all allocation requests fail early rather than cause disruptive
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reclaim (one round of reclaim in this implementation). The OOM killer
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is not invoked.
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* ``GFP_KERNEL | __GFP_RETRY_MAYFAIL`` - overrides the default allocator
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behavior and all allocation requests try really hard. The request
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will fail if the reclaim cannot make any progress. The OOM killer
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won't be triggered.
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* ``GFP_KERNEL | __GFP_NOFAIL`` - overrides the default allocator behavior
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and all allocation requests will loop endlessly until they succeed.
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This might be really dangerous especially for larger orders.
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2018-09-14 17:27:58 +08:00
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Selecting memory allocator
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==========================
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The most straightforward way to allocate memory is to use a function
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2019-10-25 03:50:15 +08:00
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from the kmalloc() family. And, to be on the safe side it's best to use
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routines that set memory to zero, like kzalloc(). If you need to
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allocate memory for an array, there are kmalloc_array() and kcalloc()
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2019-10-25 03:50:16 +08:00
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helpers. The helpers struct_size(), array_size() and array3_size() can
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be used to safely calculate object sizes without overflowing.
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2018-09-14 17:27:58 +08:00
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The maximal size of a chunk that can be allocated with `kmalloc` is
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limited. The actual limit depends on the hardware and the kernel
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configuration, but it is a good practice to use `kmalloc` for objects
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smaller than page size.
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mm, sl[aou]b: guarantee natural alignment for kmalloc(power-of-two)
In most configurations, kmalloc() happens to return naturally aligned
(i.e. aligned to the block size itself) blocks for power of two sizes.
That means some kmalloc() users might unknowingly rely on that
alignment, until stuff breaks when the kernel is built with e.g.
CONFIG_SLUB_DEBUG or CONFIG_SLOB, and blocks stop being aligned. Then
developers have to devise workaround such as own kmem caches with
specified alignment [1], which is not always practical, as recently
evidenced in [2].
The topic has been discussed at LSF/MM 2019 [3]. Adding a
'kmalloc_aligned()' variant would not help with code unknowingly relying
on the implicit alignment. For slab implementations it would either
require creating more kmalloc caches, or allocate a larger size and only
give back part of it. That would be wasteful, especially with a generic
alignment parameter (in contrast with a fixed alignment to size).
Ideally we should provide to mm users what they need without difficult
workarounds or own reimplementations, so let's make the kmalloc()
alignment to size explicitly guaranteed for power-of-two sizes under all
configurations. What this means for the three available allocators?
* SLAB object layout happens to be mostly unchanged by the patch. The
implicitly provided alignment could be compromised with
CONFIG_DEBUG_SLAB due to redzoning, however SLAB disables redzoning for
caches with alignment larger than unsigned long long. Practically on at
least x86 this includes kmalloc caches as they use cache line alignment,
which is larger than that. Still, this patch ensures alignment on all
arches and cache sizes.
* SLUB layout is also unchanged unless redzoning is enabled through
CONFIG_SLUB_DEBUG and boot parameter for the particular kmalloc cache.
With this patch, explicit alignment is guaranteed with redzoning as
well. This will result in more memory being wasted, but that should be
acceptable in a debugging scenario.
* SLOB has no implicit alignment so this patch adds it explicitly for
kmalloc(). The potential downside is increased fragmentation. While
pathological allocation scenarios are certainly possible, in my testing,
after booting a x86_64 kernel+userspace with virtme, around 16MB memory
was consumed by slab pages both before and after the patch, with
difference in the noise.
[1] https://lore.kernel.org/linux-btrfs/c3157c8e8e0e7588312b40c853f65c02fe6c957a.1566399731.git.christophe.leroy@c-s.fr/
[2] https://lore.kernel.org/linux-fsdevel/20190225040904.5557-1-ming.lei@redhat.com/
[3] https://lwn.net/Articles/787740/
[akpm@linux-foundation.org: documentation fixlet, per Matthew]
Link: http://lkml.kernel.org/r/20190826111627.7505-3-vbabka@suse.cz
Signed-off-by: Vlastimil Babka <vbabka@suse.cz>
Reviewed-by: Matthew Wilcox (Oracle) <willy@infradead.org>
Acked-by: Michal Hocko <mhocko@suse.com>
Acked-by: Kirill A. Shutemov <kirill.shutemov@linux.intel.com>
Acked-by: Christoph Hellwig <hch@lst.de>
Cc: David Sterba <dsterba@suse.cz>
Cc: Christoph Lameter <cl@linux.com>
Cc: Pekka Enberg <penberg@kernel.org>
Cc: David Rientjes <rientjes@google.com>
Cc: Ming Lei <ming.lei@redhat.com>
Cc: Dave Chinner <david@fromorbit.com>
Cc: "Darrick J . Wong" <darrick.wong@oracle.com>
Cc: Christoph Hellwig <hch@lst.de>
Cc: James Bottomley <James.Bottomley@HansenPartnership.com>
Cc: Vlastimil Babka <vbabka@suse.cz>
Cc: Joonsoo Kim <iamjoonsoo.kim@lge.com>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
2019-10-07 08:58:45 +08:00
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The address of a chunk allocated with `kmalloc` is aligned to at least
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ARCH_KMALLOC_MINALIGN bytes. For sizes which are a power of two, the
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alignment is also guaranteed to be at least the respective size.
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2020-12-15 11:03:55 +08:00
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Chunks allocated with kmalloc() can be resized with krealloc(). Similarly
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to kmalloc_array(): a helper for resizing arrays is provided in the form of
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krealloc_array().
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2019-10-25 03:50:15 +08:00
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For large allocations you can use vmalloc() and vzalloc(), or directly
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request pages from the page allocator. The memory allocated by `vmalloc`
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and related functions is not physically contiguous.
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2018-09-14 17:27:58 +08:00
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If you are not sure whether the allocation size is too large for
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2019-10-25 03:50:15 +08:00
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`kmalloc`, it is possible to use kvmalloc() and its derivatives. It will
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try to allocate memory with `kmalloc` and if the allocation fails it
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will be retried with `vmalloc`. There are restrictions on which GFP
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flags can be used with `kvmalloc`; please see kvmalloc_node() reference
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documentation. Note that `kvmalloc` may return memory that is not
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physically contiguous.
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2018-09-14 17:27:58 +08:00
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If you need to allocate many identical objects you can use the slab
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2019-10-25 03:50:15 +08:00
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cache allocator. The cache should be set up with kmem_cache_create() or
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kmem_cache_create_usercopy() before it can be used. The second function
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should be used if a part of the cache might be copied to the userspace.
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After the cache is created kmem_cache_alloc() and its convenience
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wrappers can allocate memory from that cache.
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When the allocated memory is no longer needed it must be freed. You can
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use kvfree() for the memory allocated with `kmalloc`, `vmalloc` and
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`kvmalloc`. The slab caches should be freed with kmem_cache_free(). And
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don't forget to destroy the cache with kmem_cache_destroy().
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