198 lines
7.0 KiB
ReStructuredText
198 lines
7.0 KiB
ReStructuredText
.. _memory_management_api_virtual_memory:
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Virtual Memory
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##############
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Virtual memory (VM) in Zephyr provides developers with the ability to fine tune
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access to memory. To utilize virtual memory, the platform must support
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Memory Management Unit (MMU) and it must be enabled in the build. Due to
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the target of Zephyr mainly being embedded systems, virtual memory
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support in Zephyr differs a bit from that in traditional operating
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systems:
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Mapping of Kernel Image
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Default is to do 1:1 mapping for the kernel image (including code and data)
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between physical and virtual memory address spaces, if demand paging
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is not enabled. Deviation from this requires careful manipulation of
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linker script.
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Secondary Storage
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Basic virtual memory support does not utilize secondary storage to
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extend usable memory. The maximum usable memory is the same as
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the physical memory.
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* :ref:`memory_management_api_demand_paging` enables utilizing
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secondary storage as a backing store for virtual memory, thus
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allowing larger usable memory than the available physical memory.
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Note that demand paging needs to be explicitly enabled.
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* Although the virtual memory space can be larger than physical
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memory space, without enabling demand paging, all virtually
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mapped memory must be backed by physical memory.
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Kconfigs
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********
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Required
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========
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These are the Kconfigs that need to be enabled or defined for kernel to support
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virtual memory.
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* :kconfig:option:`CONFIG_MMU`: must be enabled for virtual memory support in
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kernel.
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* :kconfig:option:`CONFIG_MMU_PAGE_SIZE`: size of a memory page. Default is 4KB.
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* :kconfig:option:`CONFIG_KERNEL_VM_BASE`: base address of virtual address space.
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* :kconfig:option:`CONFIG_KERNEL_VM_SIZE`: size of virtual address space.
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Default is 8MB.
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* :kconfig:option:`CONFIG_KERNEL_VM_OFFSET`: kernel image starts at this offset
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from :kconfig:option:`CONFIG_KERNEL_VM_BASE`.
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Optional
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========
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* :kconfig:option:`CONFIG_KERNEL_DIRECT_MAP`: permits 1:1 mappings between
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virtual and physical addresses, instead of kernel choosing addresses within
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the virtual address space. This is useful for mapping device MMIO regions for
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more precise access control.
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Memory Map Overview
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*******************
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This is an overview of the memory map of the virtual memory address space.
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Note that the ``Z_*`` macros, which are used in code, may have different
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meanings depending on architecture and Kconfigs, which will be explained
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below.
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.. code-block:: none
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:emphasize-lines: 1, 3, 9, 22, 24
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+--------------+ <- Z_VIRT_RAM_START
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| Undefined VM | <- architecture specific reserved area
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+--------------+ <- Z_KERNEL_VIRT_START
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| Mapping for |
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| main kernel |
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| image |
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+--------------+ <- Z_FREE_VM_START
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| Unused, |
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| Available VM |
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|..............| <- grows downward as more mappings are made
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| Mapping |
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+--------------+
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| Mapping |
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+--------------+
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| ... |
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+--------------+
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| Mapping |
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+--------------+ <- memory mappings start here
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| Reserved | <- special purpose virtual page(s) of size Z_VM_RESERVED
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+--------------+ <- Z_VIRT_RAM_END
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* ``Z_VIRT_RAM_START`` is the beginning of the virtual memory address space.
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This needs to be page aligned. Currently, it is the same as
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:kconfig:option:`CONFIG_KERNEL_VM_BASE`.
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* ``Z_VIRT_RAM_SIZE`` is the size of the virtual memory address space.
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This needs to be page aligned. Currently, it is the same as
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:kconfig:option:`CONFIG_KERNEL_VM_SIZE`.
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* ``Z_VIRT_RAM_END`` is simply (``Z_VIRT_RAM_START`` + ``Z_VIRT_RAM_SIZE``).
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* ``Z_KERNEL_VIRT_START`` is the same as ``z_mapped_start`` specified in the linker
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script. This is the virtual address of the beginning of the kernel image at
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boot time.
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* ``Z_KERNEL_VIRT_END`` is the same as ``z_mapped_end`` specified in the linker
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script. This is the virtual address of the end of the kernel image at boot time.
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* ``Z_FREE_VM_START`` is the beginning of the virtual address space where addresses
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can be allocated for memory mapping. This depends on whether
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:kconfig:option:`CONFIG_ARCH_MAPS_ALL_RAM` is enabled.
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* If it is enabled, which means all physical memory are mapped in virtual
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memory address space, and it is the same as
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(:kconfig:option:`CONFIG_SRAM_BASE_ADDRESS` + :kconfig:option:`CONFIG_SRAM_SIZE`).
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* If it is disabled, ``Z_FREE_VM_START`` is the same ``Z_KERNEL_VIRT_END`` which
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is the end of the kernel image.
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* ``Z_VM_RESERVED`` is an area reserved to support kernel functions. For example,
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some addresses are reserved to support demand paging.
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Virtual Memory Mappings
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***********************
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Setting up Mappings at Boot
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===========================
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In general, most supported architectures set up the memory mappings at boot as
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following:
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* ``.text`` section is read-only and executable. It is accessible in
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both kernel and user modes.
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* ``.rodata`` section is read-only and non-executable. It is accessible
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in both kernel and user modes.
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* Other kernel sections, such as ``.data``, ``.bss`` and ``.noinit``, are
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read-write and non-executable. They are only accessible in kernel mode.
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* Stacks for user mode threads are automatically granted read-write access
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to their corresponding user mode threads during thread creation.
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* Global variables, by default, are not accessible to user mode threads.
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Refer to :ref:`Memory Domains and Partitions<memory_domain>` on how to
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use global variables in user mode threads, and on how to share data
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between user mode threads.
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Caching modes for these mappings are architecture specific. They can be
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none, write-back, or write-through.
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Note that SoCs have their own additional mappings required to boot where
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these mappings are defined under their own SoC configurations. These mappings
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usually include device MMIO regions needed to setup the hardware.
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Mapping Anonymous Memory
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========================
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The unused physical memory can be mapped in virtual address space on demand.
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This is conceptually similar to memory allocation from heap, but these
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mappings must be aligned on page size and have finer access control.
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* :c:func:`k_mem_map` can be used to map unused physical memory:
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* The requested size must be multiple of page size.
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* The address returned is inside the virtual address space between
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``Z_FREE_VM_START`` and ``Z_VIRT_RAM_END``.
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* The mapped region is not guaranteed to be physically contiguous in memory.
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* Guard pages immediately before and after the mapped virtual region are
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automatically allocated to catch access issue due to buffer underrun
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or overrun.
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* The mapped region can be unmapped (i.e. freed) via :c:func:`k_mem_unmap`:
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* Caution must be exercised to give the pass the same region size to
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both :c:func:`k_mem_map` and :c:func:`k_mem_unmap`. The unmapping
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function does not check if it is a valid mapped region before unmapping.
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API Reference
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*************
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.. doxygengroup:: kernel_memory_management
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