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Extend page_tables.rst by adding a section about the role of MMU and TLB in translating between virtual addresses and physical page frames. Furthermore explain the concept behind Page Faults and how the Linux kernel handles TLB misses. Finally briefly explain how and why to disable the page faults handler. Cc: Andrew Morton <akpm@linux-foundation.org> Cc: Ira Weiny <ira.weiny@intel.com> Cc: Jonathan Cameron <Jonathan.Cameron@huawei.com> Cc: Jonathan Corbet <corbet@lwn.net> Cc: Linus Walleij <linus.walleij@linaro.org> Cc: Matthew Wilcox <willy@infradead.org> Cc: Mike Rapoport <rppt@kernel.org> Cc: Randy Dunlap <rdunlap@infradead.org> Reviewed-by: Linus Walleij <linus.walleij@linaro.org> Signed-off-by: "Fabio M. De Francesco" <fmdefrancesco@gmail.com> Acked-by: "Mike Rapoport (IBM)" <rppt@kernel.org> Signed-off-by: Jonathan Corbet <corbet@lwn.net> Link: https://lore.kernel.org/r/20230818112726.6156-1-fmdefrancesco@gmail.com
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ReStructuredText
282 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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===========
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Page Tables
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===========
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Paged virtual memory was invented along with virtual memory as a concept in
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1962 on the Ferranti Atlas Computer which was the first computer with paged
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virtual memory. The feature migrated to newer computers and became a de facto
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feature of all Unix-like systems as time went by. In 1985 the feature was
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included in the Intel 80386, which was the CPU Linux 1.0 was developed on.
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Page tables map virtual addresses as seen by the CPU into physical addresses
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as seen on the external memory bus.
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Linux defines page tables as a hierarchy which is currently five levels in
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height. The architecture code for each supported architecture will then
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map this to the restrictions of the hardware.
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The physical address corresponding to the virtual address is often referenced
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by the underlying physical page frame. The **page frame number** or **pfn**
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is the physical address of the page (as seen on the external memory bus)
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divided by `PAGE_SIZE`.
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Physical memory address 0 will be *pfn 0* and the highest pfn will be
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the last page of physical memory the external address bus of the CPU can
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address.
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With a page granularity of 4KB and a address range of 32 bits, pfn 0 is at
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address 0x00000000, pfn 1 is at address 0x00001000, pfn 2 is at 0x00002000
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and so on until we reach pfn 0xfffff at 0xfffff000. With 16KB pages pfs are
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at 0x00004000, 0x00008000 ... 0xffffc000 and pfn goes from 0 to 0x3fffff.
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As you can see, with 4KB pages the page base address uses bits 12-31 of the
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address, and this is why `PAGE_SHIFT` in this case is defined as 12 and
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`PAGE_SIZE` is usually defined in terms of the page shift as `(1 << PAGE_SHIFT)`
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Over time a deeper hierarchy has been developed in response to increasing memory
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sizes. When Linux was created, 4KB pages and a single page table called
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`swapper_pg_dir` with 1024 entries was used, covering 4MB which coincided with
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the fact that Torvald's first computer had 4MB of physical memory. Entries in
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this single table were referred to as *PTE*:s - page table entries.
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The software page table hierarchy reflects the fact that page table hardware has
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become hierarchical and that in turn is done to save page table memory and
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speed up mapping.
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One could of course imagine a single, linear page table with enormous amounts
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of entries, breaking down the whole memory into single pages. Such a page table
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would be very sparse, because large portions of the virtual memory usually
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remains unused. By using hierarchical page tables large holes in the virtual
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address space does not waste valuable page table memory, because it will suffice
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to mark large areas as unmapped at a higher level in the page table hierarchy.
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Additionally, on modern CPUs, a higher level page table entry can point directly
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to a physical memory range, which allows mapping a contiguous range of several
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megabytes or even gigabytes in a single high-level page table entry, taking
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shortcuts in mapping virtual memory to physical memory: there is no need to
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traverse deeper in the hierarchy when you find a large mapped range like this.
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The page table hierarchy has now developed into this::
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+-----+
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| PGD |
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+-----+
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| +-----+
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+-->| P4D |
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+-----+
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| +-----+
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+-->| PUD |
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+-----+
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+-->| PMD |
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+-----+
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| +-----+
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+-->| PTE |
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+-----+
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Symbols on the different levels of the page table hierarchy have the following
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meaning beginning from the bottom:
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- **pte**, `pte_t`, `pteval_t` = **Page Table Entry** - mentioned earlier.
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The *pte* is an array of `PTRS_PER_PTE` elements of the `pteval_t` type, each
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mapping a single page of virtual memory to a single page of physical memory.
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The architecture defines the size and contents of `pteval_t`.
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A typical example is that the `pteval_t` is a 32- or 64-bit value with the
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upper bits being a **pfn** (page frame number), and the lower bits being some
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architecture-specific bits such as memory protection.
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The **entry** part of the name is a bit confusing because while in Linux 1.0
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this did refer to a single page table entry in the single top level page
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table, it was retrofitted to be an array of mapping elements when two-level
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page tables were first introduced, so the *pte* is the lowermost page
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*table*, not a page table *entry*.
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- **pmd**, `pmd_t`, `pmdval_t` = **Page Middle Directory**, the hierarchy right
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above the *pte*, with `PTRS_PER_PMD` references to the *pte*:s.
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- **pud**, `pud_t`, `pudval_t` = **Page Upper Directory** was introduced after
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the other levels to handle 4-level page tables. It is potentially unused,
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or *folded* as we will discuss later.
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- **p4d**, `p4d_t`, `p4dval_t` = **Page Level 4 Directory** was introduced to
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handle 5-level page tables after the *pud* was introduced. Now it was clear
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that we needed to replace *pgd*, *pmd*, *pud* etc with a figure indicating the
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directory level and that we cannot go on with ad hoc names any more. This
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is only used on systems which actually have 5 levels of page tables, otherwise
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it is folded.
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- **pgd**, `pgd_t`, `pgdval_t` = **Page Global Directory** - the Linux kernel
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main page table handling the PGD for the kernel memory is still found in
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`swapper_pg_dir`, but each userspace process in the system also has its own
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memory context and thus its own *pgd*, found in `struct mm_struct` which
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in turn is referenced to in each `struct task_struct`. So tasks have memory
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context in the form of a `struct mm_struct` and this in turn has a
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`struct pgt_t *pgd` pointer to the corresponding page global directory.
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To repeat: each level in the page table hierarchy is a *array of pointers*, so
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the **pgd** contains `PTRS_PER_PGD` pointers to the next level below, **p4d**
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contains `PTRS_PER_P4D` pointers to **pud** items and so on. The number of
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pointers on each level is architecture-defined.::
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PMD
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--> +-----+ PTE
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| ptr |-------> +-----+
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| ptr |- | ptr |-------> PAGE
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| ptr | \ | ptr |
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| ptr | \ ...
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| ... | \
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| ptr | \ PTE
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+-----+ +----> +-----+
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| ptr |-------> PAGE
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| ptr |
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...
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Page Table Folding
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==================
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If the architecture does not use all the page table levels, they can be *folded*
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which means skipped, and all operations performed on page tables will be
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compile-time augmented to just skip a level when accessing the next lower
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level.
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Page table handling code that wishes to be architecture-neutral, such as the
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virtual memory manager, will need to be written so that it traverses all of the
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currently five levels. This style should also be preferred for
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architecture-specific code, so as to be robust to future changes.
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MMU, TLB, and Page Faults
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=========================
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The `Memory Management Unit (MMU)` is a hardware component that handles virtual
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to physical address translations. It may use relatively small caches in hardware
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called `Translation Lookaside Buffers (TLBs)` and `Page Walk Caches` to speed up
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these translations.
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When CPU accesses a memory location, it provides a virtual address to the MMU,
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which checks if there is the existing translation in the TLB or in the Page
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Walk Caches (on architectures that support them). If no translation is found,
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MMU uses the page walks to determine the physical address and create the map.
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The dirty bit for a page is set (i.e., turned on) when the page is written to.
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Each page of memory has associated permission and dirty bits. The latter
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indicate that the page has been modified since it was loaded into memory.
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If nothing prevents it, eventually the physical memory can be accessed and the
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requested operation on the physical frame is performed.
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There are several reasons why the MMU can't find certain translations. It could
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happen because the CPU is trying to access memory that the current task is not
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permitted to, or because the data is not present into physical memory.
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When these conditions happen, the MMU triggers page faults, which are types of
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exceptions that signal the CPU to pause the current execution and run a special
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function to handle the mentioned exceptions.
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There are common and expected causes of page faults. These are triggered by
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process management optimization techniques called "Lazy Allocation" and
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"Copy-on-Write". Page faults may also happen when frames have been swapped out
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to persistent storage (swap partition or file) and evicted from their physical
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locations.
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These techniques improve memory efficiency, reduce latency, and minimize space
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occupation. This document won't go deeper into the details of "Lazy Allocation"
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and "Copy-on-Write" because these subjects are out of scope as they belong to
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Process Address Management.
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Swapping differentiates itself from the other mentioned techniques because it's
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undesirable since it's performed as a means to reduce memory under heavy
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pressure.
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Swapping can't work for memory mapped by kernel logical addresses. These are a
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subset of the kernel virtual space that directly maps a contiguous range of
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physical memory. Given any logical address, its physical address is determined
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with simple arithmetic on an offset. Accesses to logical addresses are fast
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because they avoid the need for complex page table lookups at the expenses of
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frames not being evictable and pageable out.
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If the kernel fails to make room for the data that must be present in the
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physical frames, the kernel invokes the out-of-memory (OOM) killer to make room
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by terminating lower priority processes until pressure reduces under a safe
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threshold.
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Additionally, page faults may be also caused by code bugs or by maliciously
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crafted addresses that the CPU is instructed to access. A thread of a process
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could use instructions to address (non-shared) memory which does not belong to
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its own address space, or could try to execute an instruction that want to write
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to a read-only location.
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If the above-mentioned conditions happen in user-space, the kernel sends a
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`Segmentation Fault` (SIGSEGV) signal to the current thread. That signal usually
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causes the termination of the thread and of the process it belongs to.
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This document is going to simplify and show an high altitude view of how the
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Linux kernel handles these page faults, creates tables and tables' entries,
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check if memory is present and, if not, requests to load data from persistent
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storage or from other devices, and updates the MMU and its caches.
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The first steps are architecture dependent. Most architectures jump to
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`do_page_fault()`, whereas the x86 interrupt handler is defined by the
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`DEFINE_IDTENTRY_RAW_ERRORCODE()` macro which calls `handle_page_fault()`.
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Whatever the routes, all architectures end up to the invocation of
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`handle_mm_fault()` which, in turn, (likely) ends up calling
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`__handle_mm_fault()` to carry out the actual work of allocating the page
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tables.
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The unfortunate case of not being able to call `__handle_mm_fault()` means
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that the virtual address is pointing to areas of physical memory which are not
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permitted to be accessed (at least from the current context). This
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condition resolves to the kernel sending the above-mentioned SIGSEGV signal
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to the process and leads to the consequences already explained.
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`__handle_mm_fault()` carries out its work by calling several functions to
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find the entry's offsets of the upper layers of the page tables and allocate
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the tables that it may need.
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The functions that look for the offset have names like `*_offset()`, where the
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"*" is for pgd, p4d, pud, pmd, pte; instead the functions to allocate the
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corresponding tables, layer by layer, are called `*_alloc`, using the
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above-mentioned convention to name them after the corresponding types of tables
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in the hierarchy.
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The page table walk may end at one of the middle or upper layers (PMD, PUD).
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Linux supports larger page sizes than the usual 4KB (i.e., the so called
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`huge pages`). When using these kinds of larger pages, higher level pages can
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directly map them, with no need to use lower level page entries (PTE). Huge
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pages contain large contiguous physical regions that usually span from 2MB to
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1GB. They are respectively mapped by the PMD and PUD page entries.
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The huge pages bring with them several benefits like reduced TLB pressure,
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reduced page table overhead, memory allocation efficiency, and performance
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improvement for certain workloads. However, these benefits come with
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trade-offs, like wasted memory and allocation challenges.
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At the very end of the walk with allocations, if it didn't return errors,
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`__handle_mm_fault()` finally calls `handle_pte_fault()`, which via `do_fault()`
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performs one of `do_read_fault()`, `do_cow_fault()`, `do_shared_fault()`.
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"read", "cow", "shared" give hints about the reasons and the kind of fault it's
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handling.
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The actual implementation of the workflow is very complex. Its design allows
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Linux to handle page faults in a way that is tailored to the specific
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characteristics of each architecture, while still sharing a common overall
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structure.
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To conclude this high altitude view of how Linux handles page faults, let's
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add that the page faults handler can be disabled and enabled respectively with
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`pagefault_disable()` and `pagefault_enable()`.
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Several code path make use of the latter two functions because they need to
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disable traps into the page faults handler, mostly to prevent deadlocks.
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