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To reflect the updates to free_area_init() family of functions. Signed-off-by: Mike Rapoport <rppt@linux.ibm.com> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Tested-by: Hoan Tran <hoan@os.amperecomputing.com> [arm64] Cc: Baoquan He <bhe@redhat.com> Cc: Brian Cain <bcain@codeaurora.org> Cc: Catalin Marinas <catalin.marinas@arm.com> Cc: "David S. Miller" <davem@davemloft.net> Cc: Geert Uytterhoeven <geert@linux-m68k.org> Cc: Greentime Hu <green.hu@gmail.com> Cc: Greg Ungerer <gerg@linux-m68k.org> Cc: Guan Xuetao <gxt@pku.edu.cn> Cc: Guo Ren <guoren@kernel.org> Cc: Heiko Carstens <heiko.carstens@de.ibm.com> Cc: Helge Deller <deller@gmx.de> Cc: "James E.J. Bottomley" <James.Bottomley@HansenPartnership.com> Cc: Jonathan Corbet <corbet@lwn.net> Cc: Ley Foon Tan <ley.foon.tan@intel.com> Cc: Mark Salter <msalter@redhat.com> Cc: Matt Turner <mattst88@gmail.com> Cc: Max Filippov <jcmvbkbc@gmail.com> Cc: Michael Ellerman <mpe@ellerman.id.au> Cc: Michal Hocko <mhocko@kernel.org> Cc: Michal Simek <monstr@monstr.eu> Cc: Nick Hu <nickhu@andestech.com> Cc: Paul Walmsley <paul.walmsley@sifive.com> Cc: Richard Weinberger <richard@nod.at> Cc: Rich Felker <dalias@libc.org> Cc: Russell King <linux@armlinux.org.uk> Cc: Stafford Horne <shorne@gmail.com> Cc: Thomas Bogendoerfer <tsbogend@alpha.franken.de> Cc: Tony Luck <tony.luck@intel.com> Cc: Vineet Gupta <vgupta@synopsys.com> Cc: Yoshinori Sato <ysato@users.sourceforge.jp> Link: http://lkml.kernel.org/r/20200412194859.12663-22-rppt@kernel.org Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
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223 lines
9.9 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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.. _physical_memory_model:
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=====================
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Physical Memory Model
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=====================
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Physical memory in a system may be addressed in different ways. The
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simplest case is when the physical memory starts at address 0 and
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spans a contiguous range up to the maximal address. It could be,
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however, that this range contains small holes that are not accessible
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for the CPU. Then there could be several contiguous ranges at
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completely distinct addresses. And, don't forget about NUMA, where
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different memory banks are attached to different CPUs.
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Linux abstracts this diversity using one of the three memory models:
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FLATMEM, DISCONTIGMEM and SPARSEMEM. Each architecture defines what
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memory models it supports, what the default memory model is and
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whether it is possible to manually override that default.
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.. note::
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At time of this writing, DISCONTIGMEM is considered deprecated,
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although it is still in use by several architectures.
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All the memory models track the status of physical page frames using
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:c:type:`struct page` arranged in one or more arrays.
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Regardless of the selected memory model, there exists one-to-one
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mapping between the physical page frame number (PFN) and the
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corresponding `struct page`.
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Each memory model defines :c:func:`pfn_to_page` and :c:func:`page_to_pfn`
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helpers that allow the conversion from PFN to `struct page` and vice
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versa.
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FLATMEM
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=======
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The simplest memory model is FLATMEM. This model is suitable for
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non-NUMA systems with contiguous, or mostly contiguous, physical
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memory.
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In the FLATMEM memory model, there is a global `mem_map` array that
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maps the entire physical memory. For most architectures, the holes
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have entries in the `mem_map` array. The `struct page` objects
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corresponding to the holes are never fully initialized.
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To allocate the `mem_map` array, architecture specific setup code should
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call :c:func:`free_area_init` function. Yet, the mappings array is not
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usable until the call to :c:func:`memblock_free_all` that hands all the
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memory to the page allocator.
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If an architecture enables `CONFIG_ARCH_HAS_HOLES_MEMORYMODEL` option,
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it may free parts of the `mem_map` array that do not cover the
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actual physical pages. In such case, the architecture specific
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:c:func:`pfn_valid` implementation should take the holes in the
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`mem_map` into account.
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With FLATMEM, the conversion between a PFN and the `struct page` is
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straightforward: `PFN - ARCH_PFN_OFFSET` is an index to the
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`mem_map` array.
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The `ARCH_PFN_OFFSET` defines the first page frame number for
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systems with physical memory starting at address different from 0.
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DISCONTIGMEM
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============
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The DISCONTIGMEM model treats the physical memory as a collection of
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`nodes` similarly to how Linux NUMA support does. For each node Linux
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constructs an independent memory management subsystem represented by
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`struct pglist_data` (or `pg_data_t` for short). Among other
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things, `pg_data_t` holds the `node_mem_map` array that maps
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physical pages belonging to that node. The `node_start_pfn` field of
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`pg_data_t` is the number of the first page frame belonging to that
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node.
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The architecture setup code should call :c:func:`free_area_init_node` for
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each node in the system to initialize the `pg_data_t` object and its
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`node_mem_map`.
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Every `node_mem_map` behaves exactly as FLATMEM's `mem_map` -
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every physical page frame in a node has a `struct page` entry in the
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`node_mem_map` array. When DISCONTIGMEM is enabled, a portion of the
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`flags` field of the `struct page` encodes the node number of the
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node hosting that page.
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The conversion between a PFN and the `struct page` in the
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DISCONTIGMEM model became slightly more complex as it has to determine
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which node hosts the physical page and which `pg_data_t` object
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holds the `struct page`.
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Architectures that support DISCONTIGMEM provide :c:func:`pfn_to_nid`
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to convert PFN to the node number. The opposite conversion helper
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:c:func:`page_to_nid` is generic as it uses the node number encoded in
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page->flags.
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Once the node number is known, the PFN can be used to index
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appropriate `node_mem_map` array to access the `struct page` and
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the offset of the `struct page` from the `node_mem_map` plus
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`node_start_pfn` is the PFN of that page.
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SPARSEMEM
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=========
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SPARSEMEM is the most versatile memory model available in Linux and it
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is the only memory model that supports several advanced features such
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as hot-plug and hot-remove of the physical memory, alternative memory
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maps for non-volatile memory devices and deferred initialization of
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the memory map for larger systems.
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The SPARSEMEM model presents the physical memory as a collection of
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sections. A section is represented with :c:type:`struct mem_section`
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that contains `section_mem_map` that is, logically, a pointer to an
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array of struct pages. However, it is stored with some other magic
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that aids the sections management. The section size and maximal number
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of section is specified using `SECTION_SIZE_BITS` and
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`MAX_PHYSMEM_BITS` constants defined by each architecture that
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supports SPARSEMEM. While `MAX_PHYSMEM_BITS` is an actual width of a
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physical address that an architecture supports, the
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`SECTION_SIZE_BITS` is an arbitrary value.
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The maximal number of sections is denoted `NR_MEM_SECTIONS` and
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defined as
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.. math::
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NR\_MEM\_SECTIONS = 2 ^ {(MAX\_PHYSMEM\_BITS - SECTION\_SIZE\_BITS)}
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The `mem_section` objects are arranged in a two-dimensional array
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called `mem_sections`. The size and placement of this array depend
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on `CONFIG_SPARSEMEM_EXTREME` and the maximal possible number of
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sections:
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* When `CONFIG_SPARSEMEM_EXTREME` is disabled, the `mem_sections`
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array is static and has `NR_MEM_SECTIONS` rows. Each row holds a
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single `mem_section` object.
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* When `CONFIG_SPARSEMEM_EXTREME` is enabled, the `mem_sections`
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array is dynamically allocated. Each row contains PAGE_SIZE worth of
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`mem_section` objects and the number of rows is calculated to fit
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all the memory sections.
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The architecture setup code should call :c:func:`memory_present` for
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each active memory range or use :c:func:`memblocks_present` or
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:c:func:`sparse_memory_present_with_active_regions` wrappers to
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initialize the memory sections. Next, the actual memory maps should be
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set up using :c:func:`sparse_init`.
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With SPARSEMEM there are two possible ways to convert a PFN to the
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corresponding `struct page` - a "classic sparse" and "sparse
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vmemmap". The selection is made at build time and it is determined by
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the value of `CONFIG_SPARSEMEM_VMEMMAP`.
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The classic sparse encodes the section number of a page in page->flags
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and uses high bits of a PFN to access the section that maps that page
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frame. Inside a section, the PFN is the index to the array of pages.
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The sparse vmemmap uses a virtually mapped memory map to optimize
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pfn_to_page and page_to_pfn operations. There is a global `struct
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page *vmemmap` pointer that points to a virtually contiguous array of
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`struct page` objects. A PFN is an index to that array and the the
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offset of the `struct page` from `vmemmap` is the PFN of that
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page.
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To use vmemmap, an architecture has to reserve a range of virtual
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addresses that will map the physical pages containing the memory
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map and make sure that `vmemmap` points to that range. In addition,
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the architecture should implement :c:func:`vmemmap_populate` method
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that will allocate the physical memory and create page tables for the
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virtual memory map. If an architecture does not have any special
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requirements for the vmemmap mappings, it can use default
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:c:func:`vmemmap_populate_basepages` provided by the generic memory
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management.
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The virtually mapped memory map allows storing `struct page` objects
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for persistent memory devices in pre-allocated storage on those
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devices. This storage is represented with :c:type:`struct vmem_altmap`
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that is eventually passed to vmemmap_populate() through a long chain
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of function calls. The vmemmap_populate() implementation may use the
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`vmem_altmap` along with :c:func:`altmap_alloc_block_buf` helper to
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allocate memory map on the persistent memory device.
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ZONE_DEVICE
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===========
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The `ZONE_DEVICE` facility builds upon `SPARSEMEM_VMEMMAP` to offer
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`struct page` `mem_map` services for device driver identified physical
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address ranges. The "device" aspect of `ZONE_DEVICE` relates to the fact
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that the page objects for these address ranges are never marked online,
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and that a reference must be taken against the device, not just the page
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to keep the memory pinned for active use. `ZONE_DEVICE`, via
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:c:func:`devm_memremap_pages`, performs just enough memory hotplug to
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turn on :c:func:`pfn_to_page`, :c:func:`page_to_pfn`, and
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:c:func:`get_user_pages` service for the given range of pfns. Since the
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page reference count never drops below 1 the page is never tracked as
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free memory and the page's `struct list_head lru` space is repurposed
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for back referencing to the host device / driver that mapped the memory.
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While `SPARSEMEM` presents memory as a collection of sections,
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optionally collected into memory blocks, `ZONE_DEVICE` users have a need
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for smaller granularity of populating the `mem_map`. Given that
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`ZONE_DEVICE` memory is never marked online it is subsequently never
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subject to its memory ranges being exposed through the sysfs memory
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hotplug api on memory block boundaries. The implementation relies on
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this lack of user-api constraint to allow sub-section sized memory
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ranges to be specified to :c:func:`arch_add_memory`, the top-half of
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memory hotplug. Sub-section support allows for 2MB as the cross-arch
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common alignment granularity for :c:func:`devm_memremap_pages`.
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The users of `ZONE_DEVICE` are:
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* pmem: Map platform persistent memory to be used as a direct-I/O target
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via DAX mappings.
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* hmm: Extend `ZONE_DEVICE` with `->page_fault()` and `->page_free()`
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event callbacks to allow a device-driver to coordinate memory management
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events related to device-memory, typically GPU memory. See
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Documentation/vm/hmm.rst.
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* p2pdma: Create `struct page` objects to allow peer devices in a
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PCI/-E topology to coordinate direct-DMA operations between themselves,
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i.e. bypass host memory.
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