kernel/Kconfig.vm - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 # Copyright (c) 2021 Intel Corporation
 #
 # SPDX-License-Identifier: Apache-2.0

 menu "Virtual Memory Support"

 config KERNEL_VM_SUPPORT
 	bool
 	help
 	  Hidden option to enable virtual memory Kconfigs.

 if KERNEL_VM_SUPPORT

 DT_CHOSEN_Z_SRAM := zephyr,sram

 config KERNEL_VM_BASE
 	hex "Virtual address space base address"
 	default $(dt_chosen_reg_addr_hex,$(DT_CHOSEN_Z_SRAM))
 	help
 	  Define the base of the kernel's address space.

 	  By default, this is the same as the DT_CHOSEN_Z_SRAM physical base SRAM
 	  address from DTS, in which case RAM will be identity-mapped. Some
 	  architectures may require RAM to be mapped in this way; they may have
 	  just one RAM region and doing this makes linking much simpler, as
 	  at least when the kernel boots all virtual RAM addresses are the same
 	  as their physical address (demand paging at runtime may later modify
 	  this for non-pinned page frames).

 	  Otherwise, if RAM isn't identity-mapped:
 	  1. It is the architecture's responsibility to transition the
 	  instruction pointer to virtual addresses at early boot before
 	  entering the kernel at z_cstart().
 	  2. The underlying architecture may impose constraints on the bounds of
 	  the kernel's address space, such as not overlapping physical RAM
 	  regions if RAM is not identity-mapped, or the virtual and physical
 	  base addresses being aligned to some common value (which allows
 	  double-linking of paging structures to make the instruction pointer
 	  transition simpler).

 	  Zephyr does not implement a split address space and if multiple
 	  page tables are in use, they all have the same virtual-to-physical
 	  mappings (with potentially different permissions).

 config KERNEL_VM_OFFSET
 	hex "Kernel offset within address space"
 	default 0
 	help
 	  Offset that the kernel image begins within its address space,
 	  if this is not the same offset from the beginning of RAM.

 	  Some care may need to be taken in selecting this value. In certain
 	  build-time cases, or when a physical address cannot be looked up
 	  in page tables, the equation:

 	      virt = phys + ((KERNEL_VM_BASE + KERNEL_VM_OFFSET) -
 	                     (SRAM_BASE_ADDRESS + SRAM_OFFSET))

 	  Will be used to convert between physical and virtual addresses for
 	  memory that is mapped at boot.

 	  This uncommon and is only necessary if the beginning of VM and
 	  physical memory have dissimilar alignment.

 config KERNEL_VM_SIZE
 	hex "Size of kernel address space in bytes"
 	default 0x800000
 	help
 	  Size of the kernel's address space. Constraining this helps control
 	  how much total memory can be used for page tables.

 	  The difference between KERNEL_VM_BASE and KERNEL_VM_SIZE indicates the
 	  size of the virtual region for runtime memory mappings. This is needed
 	  for mapping driver MMIO regions, as well as special RAM mapping use-cases
 	  such as VSDO pages, memory mapped thread stacks, and anonymous memory
 	  mappings. The kernel itself will be mapped in here as well at boot.

 	  Systems with very large amounts of memory (such as 512M or more)
 	  will want to use a 64-bit build of Zephyr, there are no plans to
 	  implement a notion of "high" memory in Zephyr to work around physical
 	  RAM size larger than the defined bounds of the virtual address space.

 endif # KERNEL_VM_SUPPORT

 menuconfig MMU
 	bool "MMU features"
 	depends on CPU_HAS_MMU
 	select KERNEL_VM_SUPPORT
 	help
 	  This option is enabled when the CPU's memory management unit is active
 	  and the arch_mem_map() API is available.

 if MMU
 config MMU_PAGE_SIZE
 	hex "Size of smallest granularity MMU page"
 	default 0x1000
 	help
 	  Size of memory pages. Varies per MMU but 4K is common. For MMUs that
 	  support multiple page sizes, put the smallest one here.

 menuconfig DEMAND_PAGING
 	bool "Demand paging [EXPERIMENTAL]"
 	depends on ARCH_HAS_DEMAND_PAGING
 	help
 	  Enable demand paging. Requires architecture support in how the kernel
 	  is linked and the implementation of an eviction algorithm and a
 	  backing store for evicted pages.

 if DEMAND_PAGING
 config DEMAND_PAGING_ALLOW_IRQ
 	bool "Allow interrupts during page-ins/outs"
 	help
 	  Allow interrupts to be serviced while pages are being evicted or
 	  retrieved from the backing store. This is much better for system
 	  latency, but any code running in interrupt context that page faults
 	  will cause a kernel panic. Such code must work with exclusively pinned
 	  code and data pages.

 	  The scheduler is still disabled during this operation.

 	  If this option is disabled, the page fault servicing logic
 	  runs with interrupts disabled for the entire operation. However,
 	  ISRs may also page fault.

 config DEMAND_PAGING_PAGE_FRAMES_RESERVE
 	int "Number of page frames reserved for paging"
 	default 32 if !LINKER_GENERIC_SECTIONS_PRESENT_AT_BOOT
 	default 0
 	help
 	  This sets the number of page frames that will be reserved for
 	  paging that do not count towards free memory. This is to
 	  ensure that there are some page frames available for paging
 	  code and data. Otherwise, it would be possible to exhaust
 	  all page frames via anonymous memory mappings.

 config DEMAND_PAGING_STATS
 	bool "Gather Demand Paging Statistics"
 	help
 	  This enables gathering various statistics related to demand paging,
 	  e.g. number of pagefaults. This is useful for tuning eviction
 	  algorithms and optimizing backing store.

 	  Should say N in production system as this is not without cost.

 config DEMAND_PAGING_STATS_USING_TIMING_FUNCTIONS
 	bool "Use Timing Functions to Gather Demand Paging Statistics"
 	select TIMING_FUNCTIONS_NEED_AT_BOOT
 	help
 	  Use timing functions to gather various demand paging statistics.

 config DEMAND_PAGING_THREAD_STATS
 	bool "Gather per Thread Demand Paging Statistics"
 	depends on DEMAND_PAGING_STATS
 	help
 	  This enables gathering per thread statistics related to demand
 	  paging.

 	  Should say N in production system as this is not without cost.

 config DEMAND_PAGING_TIMING_HISTOGRAM
 	bool "Gather Demand Paging Execution Timing Histogram"
 	depends on DEMAND_PAGING_STATS
 	help
 	  This gathers the histogram of execution time on page eviction
 	  selection, and backing store page in and page out.

 	  Should say N in production system as this is not without cost.

 config DEMAND_PAGING_TIMING_HISTOGRAM_NUM_BINS
 	int "Number of bins (buckets) in Demand Paging Timing Histogram"
 	depends on DEMAND_PAGING_TIMING_HISTOGRAM
 	default 10
 	help
 	  Defines the number of bins (buckets) in the histogram used for
 	  gathering execution timing information for demand paging.

 	  This requires k_mem_paging_eviction_histogram_bounds[] and
 	  k_mem_paging_backing_store_histogram_bounds[] to define
 	  the upper bounds for each bin. See kernel/statistics.c for
 	  information.

 endif # DEMAND_PAGING
 endif # MMU

 endmenu # Virtual Memory Support
	# Copyright (c) 2021 Intel Corporation
	#
	# SPDX-License-Identifier: Apache-2.0

	menu "Virtual Memory Support"

	config KERNEL_VM_SUPPORT
	bool
	help
	Hidden option to enable virtual memory Kconfigs.

	if KERNEL_VM_SUPPORT

	DT_CHOSEN_Z_SRAM := zephyr,sram

	config KERNEL_VM_BASE
	hex "Virtual address space base address"
	default $(dt_chosen_reg_addr_hex,$(DT_CHOSEN_Z_SRAM))
	help
	Define the base of the kernel's address space.

	By default, this is the same as the DT_CHOSEN_Z_SRAM physical base SRAM
	address from DTS, in which case RAM will be identity-mapped. Some
	architectures may require RAM to be mapped in this way; they may have
	just one RAM region and doing this makes linking much simpler, as
	at least when the kernel boots all virtual RAM addresses are the same
	as their physical address (demand paging at runtime may later modify
	this for non-pinned page frames).

	Otherwise, if RAM isn't identity-mapped:
	1. It is the architecture's responsibility to transition the
	instruction pointer to virtual addresses at early boot before
	entering the kernel at z_cstart().
	2. The underlying architecture may impose constraints on the bounds of
	the kernel's address space, such as not overlapping physical RAM
	regions if RAM is not identity-mapped, or the virtual and physical
	base addresses being aligned to some common value (which allows
	double-linking of paging structures to make the instruction pointer
	transition simpler).

	Zephyr does not implement a split address space and if multiple
	page tables are in use, they all have the same virtual-to-physical
	mappings (with potentially different permissions).

	config KERNEL_VM_OFFSET
	hex "Kernel offset within address space"
	default 0
	help
	Offset that the kernel image begins within its address space,
	if this is not the same offset from the beginning of RAM.

	Some care may need to be taken in selecting this value. In certain
	build-time cases, or when a physical address cannot be looked up
	in page tables, the equation:

	virt = phys + ((KERNEL_VM_BASE + KERNEL_VM_OFFSET) -
	(SRAM_BASE_ADDRESS + SRAM_OFFSET))

	Will be used to convert between physical and virtual addresses for
	memory that is mapped at boot.

	This uncommon and is only necessary if the beginning of VM and
	physical memory have dissimilar alignment.

	config KERNEL_VM_SIZE
	hex "Size of kernel address space in bytes"
	default 0x800000
	help
	Size of the kernel's address space. Constraining this helps control
	how much total memory can be used for page tables.

	The difference between KERNEL_VM_BASE and KERNEL_VM_SIZE indicates the
	size of the virtual region for runtime memory mappings. This is needed
	for mapping driver MMIO regions, as well as special RAM mapping use-cases
	such as VSDO pages, memory mapped thread stacks, and anonymous memory
	mappings. The kernel itself will be mapped in here as well at boot.

	Systems with very large amounts of memory (such as 512M or more)
	will want to use a 64-bit build of Zephyr, there are no plans to
	implement a notion of "high" memory in Zephyr to work around physical
	RAM size larger than the defined bounds of the virtual address space.

	endif # KERNEL_VM_SUPPORT

	menuconfig MMU
	bool "MMU features"
	depends on CPU_HAS_MMU
	select KERNEL_VM_SUPPORT
	help
	This option is enabled when the CPU's memory management unit is active
	and the arch_mem_map() API is available.

	if MMU
	config MMU_PAGE_SIZE
	hex "Size of smallest granularity MMU page"
	default 0x1000
	help
	Size of memory pages. Varies per MMU but 4K is common. For MMUs that
	support multiple page sizes, put the smallest one here.

	menuconfig DEMAND_PAGING
	bool "Demand paging [EXPERIMENTAL]"
	depends on ARCH_HAS_DEMAND_PAGING
	help
	Enable demand paging. Requires architecture support in how the kernel
	is linked and the implementation of an eviction algorithm and a
	backing store for evicted pages.

	if DEMAND_PAGING
	config DEMAND_PAGING_ALLOW_IRQ
	bool "Allow interrupts during page-ins/outs"
	help
	Allow interrupts to be serviced while pages are being evicted or
	retrieved from the backing store. This is much better for system
	latency, but any code running in interrupt context that page faults
	will cause a kernel panic. Such code must work with exclusively pinned
	code and data pages.

	The scheduler is still disabled during this operation.

	If this option is disabled, the page fault servicing logic
	runs with interrupts disabled for the entire operation. However,
	ISRs may also page fault.

	config DEMAND_PAGING_PAGE_FRAMES_RESERVE
	int "Number of page frames reserved for paging"
	default 32 if !LINKER_GENERIC_SECTIONS_PRESENT_AT_BOOT
	default 0
	help
	This sets the number of page frames that will be reserved for
	paging that do not count towards free memory. This is to
	ensure that there are some page frames available for paging
	code and data. Otherwise, it would be possible to exhaust
	all page frames via anonymous memory mappings.

	config DEMAND_PAGING_STATS
	bool "Gather Demand Paging Statistics"
	help
	This enables gathering various statistics related to demand paging,
	e.g. number of pagefaults. This is useful for tuning eviction
	algorithms and optimizing backing store.

	Should say N in production system as this is not without cost.

	config DEMAND_PAGING_STATS_USING_TIMING_FUNCTIONS
	bool "Use Timing Functions to Gather Demand Paging Statistics"
	select TIMING_FUNCTIONS_NEED_AT_BOOT
	help
	Use timing functions to gather various demand paging statistics.

	config DEMAND_PAGING_THREAD_STATS
	bool "Gather per Thread Demand Paging Statistics"
	depends on DEMAND_PAGING_STATS
	help
	This enables gathering per thread statistics related to demand
	paging.

	Should say N in production system as this is not without cost.

	config DEMAND_PAGING_TIMING_HISTOGRAM
	bool "Gather Demand Paging Execution Timing Histogram"
	depends on DEMAND_PAGING_STATS
	help
	This gathers the histogram of execution time on page eviction
	selection, and backing store page in and page out.

	Should say N in production system as this is not without cost.

	config DEMAND_PAGING_TIMING_HISTOGRAM_NUM_BINS
	int "Number of bins (buckets) in Demand Paging Timing Histogram"
	depends on DEMAND_PAGING_TIMING_HISTOGRAM
	default 10
	help
	Defines the number of bins (buckets) in the histogram used for
	gathering execution timing information for demand paging.

	This requires k_mem_paging_eviction_histogram_bounds[] and
	k_mem_paging_backing_store_histogram_bounds[] to define
	the upper bounds for each bin. See kernel/statistics.c for
	information.

	endif # DEMAND_PAGING
	endif # MMU

	endmenu # Virtual Memory Support