xref: /linux-master/arch/arm/mm/Kconfig

# SPDX-License-Identifier: GPL-2.0
comment "Processor Type"

# Select CPU types depending on the architecture selected.  This selects
# which CPUs we support in the kernel image, and the compiler instruction
# optimiser behaviour.

# ARM7TDMI
config CPU_ARM7TDMI
	bool
	depends on !MMU
	select CPU_32v4T
	select CPU_ABRT_LV4T
	select CPU_CACHE_V4
	select CPU_PABRT_LEGACY
	help
	  A 32-bit RISC microprocessor based on the ARM7 processor core
	  which has no memory control unit and cache.

	  Say Y if you want support for the ARM7TDMI processor.
	  Otherwise, say N.

# ARM720T
config CPU_ARM720T
	bool
	select CPU_32v4T
	select CPU_ABRT_LV4T
	select CPU_CACHE_V4
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WT if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WT if MMU
	help
	  A 32-bit RISC processor with 8kByte Cache, Write Buffer and
	  MMU built around an ARM7TDMI core.

	  Say Y if you want support for the ARM720T processor.
	  Otherwise, say N.

# ARM740T
config CPU_ARM740T
	bool
	depends on !MMU
	select CPU_32v4T
	select CPU_ABRT_LV4T
	select CPU_CACHE_V4
	select CPU_CP15_MPU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	help
	  A 32-bit RISC processor with 8KB cache or 4KB variants,
	  write buffer and MPU(Protection Unit) built around
	  an ARM7TDMI core.

	  Say Y if you want support for the ARM740T processor.
	  Otherwise, say N.

# ARM9TDMI
config CPU_ARM9TDMI
	bool
	depends on !MMU
	select CPU_32v4T
	select CPU_ABRT_NOMMU
	select CPU_CACHE_V4
	select CPU_PABRT_LEGACY
	help
	  A 32-bit RISC microprocessor based on the ARM9 processor core
	  which has no memory control unit and cache.

	  Say Y if you want support for the ARM9TDMI processor.
	  Otherwise, say N.

# ARM920T
config CPU_ARM920T
	bool
	select CPU_32v4T
	select CPU_ABRT_EV4T
	select CPU_CACHE_V4WT
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  The ARM920T is licensed to be produced by numerous vendors,
	  and is used in the Cirrus EP93xx and the Samsung S3C2410.

	  Say Y if you want support for the ARM920T processor.
	  Otherwise, say N.

# ARM922T
config CPU_ARM922T
	bool
	select CPU_32v4T
	select CPU_ABRT_EV4T
	select CPU_CACHE_V4WT
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  The ARM922T is a version of the ARM920T, but with smaller
	  instruction and data caches. It is used in Altera's
	  Excalibur XA device family and the ARM Integrator.

	  Say Y if you want support for the ARM922T processor.
	  Otherwise, say N.

# ARM925T
config CPU_ARM925T
	bool
	select CPU_32v4T
	select CPU_ABRT_EV4T
	select CPU_CACHE_V4WT
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
 	help
 	  The ARM925T is a mix between the ARM920T and ARM926T, but with
	  different instruction and data caches. It is used in TI's OMAP
 	  device family.

 	  Say Y if you want support for the ARM925T processor.
 	  Otherwise, say N.

# ARM926T
config CPU_ARM926T
	bool
	select CPU_32v5
	select CPU_ABRT_EV5TJ
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  This is a variant of the ARM920.  It has slightly different
	  instruction sequences for cache and TLB operations.  Curiously,
	  there is no documentation on it at the ARM corporate website.

	  Say Y if you want support for the ARM926T processor.
	  Otherwise, say N.

# FA526
config CPU_FA526
	bool
	select CPU_32v4
	select CPU_ABRT_EV4
	select CPU_CACHE_FA
	select CPU_CACHE_VIVT
	select CPU_COPY_FA if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_TLB_FA if MMU
	help
	  The FA526 is a version of the ARMv4 compatible processor with
	  Branch Target Buffer, Unified TLB and cache line size 16.

	  Say Y if you want support for the FA526 processor.
	  Otherwise, say N.

# ARM940T
config CPU_ARM940T
	bool
	depends on !MMU
	select CPU_32v4T
	select CPU_ABRT_NOMMU
	select CPU_CACHE_VIVT
	select CPU_CP15_MPU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	help
	  ARM940T is a member of the ARM9TDMI family of general-
	  purpose microprocessors with MPU and separate 4KB
	  instruction and 4KB data cases, each with a 4-word line
	  length.

	  Say Y if you want support for the ARM940T processor.
	  Otherwise, say N.

# ARM946E-S
config CPU_ARM946E
	bool
	depends on !MMU
	select CPU_32v5
	select CPU_ABRT_NOMMU
	select CPU_CACHE_VIVT
	select CPU_CP15_MPU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	help
	  ARM946E-S is a member of the ARM9E-S family of high-
	  performance, 32-bit system-on-chip processor solutions.
	  The TCM and ARMv5TE 32-bit instruction set is supported.

	  Say Y if you want support for the ARM946E-S processor.
	  Otherwise, say N.

# ARM1020 - needs validating
config CPU_ARM1020
	bool
	select CPU_32v5
	select CPU_ABRT_EV4T
	select CPU_CACHE_V4WT
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  The ARM1020 is the 32K cached version of the ARM10 processor,
	  with an addition of a floating-point unit.

	  Say Y if you want support for the ARM1020 processor.
	  Otherwise, say N.

# ARM1020E - needs validating
config CPU_ARM1020E
	bool
	depends on n
	select CPU_32v5
	select CPU_ABRT_EV4T
	select CPU_CACHE_V4WT
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU

# ARM1022E
config CPU_ARM1022
	bool
	select CPU_32v5
	select CPU_ABRT_EV4T
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU # can probably do better
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  The ARM1022E is an implementation of the ARMv5TE architecture
	  based upon the ARM10 integer core with a 16KiB L1 Harvard cache,
	  embedded trace macrocell, and a floating-point unit.

	  Say Y if you want support for the ARM1022E processor.
	  Otherwise, say N.

# ARM1026EJ-S
config CPU_ARM1026
	bool
	select CPU_32v5
	select CPU_ABRT_EV5T # But need Jazelle, but EV5TJ ignores bit 10
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU # can probably do better
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	help
	  The ARM1026EJ-S is an implementation of the ARMv5TEJ architecture
	  based upon the ARM10 integer core.

	  Say Y if you want support for the ARM1026EJ-S processor.
	  Otherwise, say N.

# SA110
config CPU_SA110
	bool
	select CPU_32v3 if ARCH_RPC
	select CPU_32v4 if !ARCH_RPC
	select CPU_ABRT_EV4
	select CPU_CACHE_V4WB
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_TLB_V4WB if MMU
	help
	  The Intel StrongARM(R) SA-110 is a 32-bit microprocessor and
	  is available at five speeds ranging from 100 MHz to 233 MHz.
	  More information is available at
	  <http://developer.intel.com/design/strong/sa110.htm>.

	  Say Y if you want support for the SA-110 processor.
	  Otherwise, say N.

# SA1100
config CPU_SA1100
	bool
	select CPU_32v4
	select CPU_ABRT_EV4
	select CPU_CACHE_V4WB
	select CPU_CACHE_VIVT
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_TLB_V4WB if MMU

# XScale
config CPU_XSCALE
	bool
	select CPU_32v5
	select CPU_ABRT_EV5T
	select CPU_CACHE_VIVT
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU

# XScale Core Version 3
config CPU_XSC3
	bool
	select CPU_32v5
	select CPU_ABRT_EV5T
	select CPU_CACHE_VIVT
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU
	select IO_36

# Marvell PJ1 (Mohawk)
config CPU_MOHAWK
	bool
	select CPU_32v5
	select CPU_ABRT_EV5T
	select CPU_CACHE_VIVT
	select CPU_COPY_V4WB if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V4WBI if MMU

# Feroceon
config CPU_FEROCEON
	bool
	select CPU_32v5
	select CPU_ABRT_EV5T
	select CPU_CACHE_VIVT
	select CPU_COPY_FEROCEON if MMU
	select CPU_CP15_MMU
	select CPU_PABRT_LEGACY
	select CPU_THUMB_CAPABLE
	select CPU_TLB_FEROCEON if MMU

config CPU_FEROCEON_OLD_ID
	bool "Accept early Feroceon cores with an ARM926 ID"
	depends on CPU_FEROCEON && !CPU_ARM926T
	default y
	help
	  This enables the usage of some old Feroceon cores
	  for which the CPU ID is equal to the ARM926 ID.
	  Relevant for Feroceon-1850 and early Feroceon-2850.

# Marvell PJ4
config CPU_PJ4
	bool
	select ARM_THUMBEE
	select CPU_V7

config CPU_PJ4B
	bool
	select CPU_V7

# ARMv6
config CPU_V6
	bool
	select CPU_32v6
	select CPU_ABRT_EV6
	select CPU_CACHE_V6
	select CPU_CACHE_VIPT
	select CPU_COPY_V6 if MMU
	select CPU_CP15_MMU
	select CPU_HAS_ASID if MMU
	select CPU_PABRT_V6
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V6 if MMU
	select SMP_ON_UP if SMP

# ARMv6k
config CPU_V6K
	bool
	select CPU_32v6
	select CPU_32v6K
	select CPU_ABRT_EV6
	select CPU_CACHE_V6
	select CPU_CACHE_VIPT
	select CPU_COPY_V6 if MMU
	select CPU_CP15_MMU
	select CPU_HAS_ASID if MMU
	select CPU_PABRT_V6
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V6 if MMU

# ARMv7 and ARMv8 architectures
config CPU_V7
	bool
	select CPU_32v6K
	select CPU_32v7
	select CPU_ABRT_EV7
	select CPU_CACHE_V7
	select CPU_CACHE_VIPT
	select CPU_COPY_V6 if MMU
	select CPU_CP15_MMU if MMU
	select CPU_CP15_MPU if !MMU
	select CPU_HAS_ASID if MMU
	select CPU_PABRT_V7
	select CPU_SPECTRE if MMU
	select CPU_THUMB_CAPABLE
	select CPU_TLB_V7 if MMU

# ARMv7M
config CPU_V7M
	bool
	select CPU_32v7M
	select CPU_ABRT_NOMMU
	select CPU_CACHE_V7M
	select CPU_CACHE_NOP
	select CPU_PABRT_LEGACY
	select CPU_THUMBONLY

config CPU_THUMBONLY
	bool
	select CPU_THUMB_CAPABLE
	# There are no CPUs available with MMU that don't implement an ARM ISA:
	depends on !MMU
	help
	  Select this if your CPU doesn't support the 32 bit ARM instructions.

config CPU_THUMB_CAPABLE
	bool
	help
	  Select this if your CPU can support Thumb mode.

# Figure out what processor architecture version we should be using.
# This defines the compiler instruction set which depends on the machine type.
config CPU_32v3
	bool
	select CPU_USE_DOMAINS if MMU
	select NEED_KUSER_HELPERS
	select TLS_REG_EMUL if SMP || !MMU
	select CPU_NO_EFFICIENT_FFS

config CPU_32v4
	bool
	select CPU_USE_DOMAINS if MMU
	select NEED_KUSER_HELPERS
	select TLS_REG_EMUL if SMP || !MMU
	select CPU_NO_EFFICIENT_FFS

config CPU_32v4T
	bool
	select CPU_USE_DOMAINS if MMU
	select NEED_KUSER_HELPERS
	select TLS_REG_EMUL if SMP || !MMU
	select CPU_NO_EFFICIENT_FFS

config CPU_32v5
	bool
	select CPU_USE_DOMAINS if MMU
	select NEED_KUSER_HELPERS
	select TLS_REG_EMUL if SMP || !MMU

config CPU_32v6
	bool
	select TLS_REG_EMUL if !CPU_32v6K && !MMU

config CPU_32v6K
	bool

config CPU_32v7
	bool

config CPU_32v7M
	bool

# The abort model
config CPU_ABRT_NOMMU
	bool

config CPU_ABRT_EV4
	bool

config CPU_ABRT_EV4T
	bool

config CPU_ABRT_LV4T
	bool

config CPU_ABRT_EV5T
	bool

config CPU_ABRT_EV5TJ
	bool

config CPU_ABRT_EV6
	bool

config CPU_ABRT_EV7
	bool

config CPU_PABRT_LEGACY
	bool

config CPU_PABRT_V6
	bool

config CPU_PABRT_V7
	bool

# The cache model
config CPU_CACHE_V4
	bool

config CPU_CACHE_V4WT
	bool

config CPU_CACHE_V4WB
	bool

config CPU_CACHE_V6
	bool

config CPU_CACHE_V7
	bool

config CPU_CACHE_NOP
	bool

config CPU_CACHE_VIVT
	bool

config CPU_CACHE_VIPT
	bool

config CPU_CACHE_FA
	bool

config CPU_CACHE_V7M
	bool

if MMU
# The copy-page model
config CPU_COPY_V4WT
	bool

config CPU_COPY_V4WB
	bool

config CPU_COPY_FEROCEON
	bool

config CPU_COPY_FA
	bool

config CPU_COPY_V6
	bool

# This selects the TLB model
config CPU_TLB_V4WT
	bool
	help
	  ARM Architecture Version 4 TLB with writethrough cache.

config CPU_TLB_V4WB
	bool
	help
	  ARM Architecture Version 4 TLB with writeback cache.

config CPU_TLB_V4WBI
	bool
	help
	  ARM Architecture Version 4 TLB with writeback cache and invalidate
	  instruction cache entry.

config CPU_TLB_FEROCEON
	bool
	help
	  Feroceon TLB (v4wbi with non-outer-cachable page table walks).

config CPU_TLB_FA
	bool
	help
	  Faraday ARM FA526 architecture, unified TLB with writeback cache
	  and invalidate instruction cache entry. Branch target buffer is
	  also supported.

config CPU_TLB_V6
	bool

config CPU_TLB_V7
	bool

endif

config CPU_HAS_ASID
	bool
	help
	  This indicates whether the CPU has the ASID register; used to
	  tag TLB and possibly cache entries.

config CPU_CP15
	bool
	help
	  Processor has the CP15 register.

config CPU_CP15_MMU
	bool
	select CPU_CP15
	help
	  Processor has the CP15 register, which has MMU related registers.

config CPU_CP15_MPU
	bool
	select CPU_CP15
	help
	  Processor has the CP15 register, which has MPU related registers.

config CPU_USE_DOMAINS
	bool
	help
	  This option enables or disables the use of domain switching
	  using the DACR (domain access control register) to protect memory
	  domains from each other. In Linux we use three domains: kernel, user
	  and IO. The domains are used to protect userspace from kernelspace
	  and to handle IO-space as a special type of memory by assigning
	  manager or client roles to running code (such as a process).

config CPU_V7M_NUM_IRQ
	int "Number of external interrupts connected to the NVIC"
	depends on CPU_V7M
	default 90 if ARCH_STM32
	default 112 if SOC_VF610
	default 240
	help
	  This option indicates the number of interrupts connected to the NVIC.
	  The value can be larger than the real number of interrupts supported
	  by the system, but must not be lower.
	  The default value is 240, corresponding to the maximum number of
	  interrupts supported by the NVIC on Cortex-M family.

	  If unsure, keep default value.

#
# CPU supports 36-bit I/O
#
config IO_36
	bool

comment "Processor Features"

config ARM_LPAE
	bool "Support for the Large Physical Address Extension"
	depends on MMU && CPU_32v7 && !CPU_32v6 && !CPU_32v5 && \
		!CPU_32v4 && !CPU_32v3
	select PHYS_ADDR_T_64BIT
	select SWIOTLB
	help
	  Say Y if you have an ARMv7 processor supporting the LPAE page
	  table format and you would like to access memory beyond the
	  4GB limit. The resulting kernel image will not run on
	  processors without the LPA extension.

	  If unsure, say N.

config ARM_PV_FIXUP
	def_bool y
	depends on ARM_LPAE && ARM_PATCH_PHYS_VIRT && ARCH_KEYSTONE

config ARM_THUMB
	bool "Support Thumb user binaries" if !CPU_THUMBONLY && EXPERT
	depends on CPU_THUMB_CAPABLE && !CPU_32v4
	default y
	help
	  Say Y if you want to include kernel support for running user space
	  Thumb binaries.

	  The Thumb instruction set is a compressed form of the standard ARM
	  instruction set resulting in smaller binaries at the expense of
	  slightly less efficient code.

	  If this option is disabled, and you run userspace that switches to
	  Thumb mode, signal handling will not work correctly, resulting in
	  segmentation faults or illegal instruction aborts.

	  If you don't know what this all is, saying Y is a safe choice.

config ARM_THUMBEE
	bool "Enable ThumbEE CPU extension"
	depends on CPU_V7
	help
	  Say Y here if you have a CPU with the ThumbEE extension and code to
	  make use of it. Say N for code that can run on CPUs without ThumbEE.

config ARM_VIRT_EXT
	bool
	default y if CPU_V7
	help
	  Enable the kernel to make use of the ARM Virtualization
	  Extensions to install hypervisors without run-time firmware
	  assistance.

	  A compliant bootloader is required in order to make maximum
	  use of this feature.  Refer to Documentation/arch/arm/booting.rst for
	  details.

config SWP_EMULATE
	bool "Emulate SWP/SWPB instructions" if !SMP
	depends on CPU_V7
	default y if SMP
	select HAVE_PROC_CPU if PROC_FS
	help
	  ARMv6 architecture deprecates use of the SWP/SWPB instructions.
	  ARMv7 multiprocessing extensions introduce the ability to disable
	  these instructions, triggering an undefined instruction exception
	  when executed. Say Y here to enable software emulation of these
	  instructions for userspace (not kernel) using LDREX/STREX.
	  Also creates /proc/cpu/swp_emulation for statistics.

	  In some older versions of glibc [<=2.8] SWP is used during futex
	  trylock() operations with the assumption that the code will not
	  be preempted. This invalid assumption may be more likely to fail
	  with SWP emulation enabled, leading to deadlock of the user
	  application.

	  NOTE: when accessing uncached shared regions, LDREX/STREX rely
	  on an external transaction monitoring block called a global
	  monitor to maintain update atomicity. If your system does not
	  implement a global monitor, this option can cause programs that
	  perform SWP operations to uncached memory to deadlock.

	  If unsure, say Y.

choice
	prompt "CPU Endianness"
	default CPU_LITTLE_ENDIAN

config CPU_LITTLE_ENDIAN
	bool "Built little-endian kernel"
	help
	  Say Y if you plan on running a kernel in little-endian mode.
	  This is the default and is used in practically all modern user
	  space builds.

config CPU_BIG_ENDIAN
	bool "Build big-endian kernel"
	depends on !LD_IS_LLD
	help
	  Say Y if you plan on running a kernel in big-endian mode.
	  This works on many machines using ARMv6 or newer processors
	  but requires big-endian user space.

	  The only ARMv5 platform with big-endian support is
	  Intel IXP4xx.

endchoice

config CPU_ENDIAN_BE8
	bool
	depends on CPU_BIG_ENDIAN
	default CPU_V6 || CPU_V6K || CPU_V7 || CPU_V7M
	help
	  Support for the BE-8 (big-endian) mode on ARMv6 and ARMv7 processors.

config CPU_ENDIAN_BE32
	bool
	depends on CPU_BIG_ENDIAN
	default !CPU_ENDIAN_BE8
	help
	  Support for the BE-32 (big-endian) mode on pre-ARMv6 processors.

config CPU_HIGH_VECTOR
	depends on !MMU && CPU_CP15 && !CPU_ARM740T
	bool "Select the High exception vector"
	help
	  Say Y here to select high exception vector(0xFFFF0000~).
	  The exception vector can vary depending on the platform
	  design in nommu mode. If your platform needs to select
	  high exception vector, say Y.
	  Otherwise or if you are unsure, say N, and the low exception
	  vector (0x00000000~) will be used.

config CPU_ICACHE_DISABLE
	bool "Disable I-Cache (I-bit)"
	depends on (CPU_CP15 && !(CPU_ARM720T || CPU_ARM740T || CPU_XSCALE || CPU_XSC3)) || CPU_V7M
	help
	  Say Y here to disable the processor instruction cache. Unless
	  you have a reason not to or are unsure, say N.

config CPU_ICACHE_MISMATCH_WORKAROUND
	bool "Workaround for I-Cache line size mismatch between CPU cores"
	depends on SMP && CPU_V7
	help
	  Some big.LITTLE systems have I-Cache line size mismatch between
	  LITTLE and big cores.  Say Y here to enable a workaround for
	  proper I-Cache support on such systems.  If unsure, say N.

config CPU_DCACHE_DISABLE
	bool "Disable D-Cache (C-bit)"
	depends on (CPU_CP15 && !SMP) || CPU_V7M
	help
	  Say Y here to disable the processor data cache. Unless
	  you have a reason not to or are unsure, say N.

config CPU_DCACHE_SIZE
	hex
	depends on CPU_ARM740T || CPU_ARM946E
	default 0x00001000 if CPU_ARM740T
	default 0x00002000 # default size for ARM946E-S
	help
	  Some cores are synthesizable to have various sized cache. For
	  ARM946E-S case, it can vary from 0KB to 1MB.
	  To support such cache operations, it is efficient to know the size
	  before compile time.
	  If your SoC is configured to have a different size, define the value
	  here with proper conditions.

config CPU_DCACHE_WRITETHROUGH
	bool "Force write through D-cache"
	depends on (CPU_ARM740T || CPU_ARM920T || CPU_ARM922T || CPU_ARM925T || CPU_ARM926T || CPU_ARM940T || CPU_ARM946E || CPU_ARM1020 || CPU_FA526) && !CPU_DCACHE_DISABLE
	default y if CPU_ARM925T
	help
	  Say Y here to use the data cache in writethrough mode. Unless you
	  specifically require this or are unsure, say N.

config CPU_CACHE_ROUND_ROBIN
	bool "Round robin I and D cache replacement algorithm"
	depends on (CPU_ARM926T || CPU_ARM946E || CPU_ARM1020) && (!CPU_ICACHE_DISABLE || !CPU_DCACHE_DISABLE)
	help
	  Say Y here to use the predictable round-robin cache replacement
	  policy.  Unless you specifically require this or are unsure, say N.

config CPU_BPREDICT_DISABLE
	bool "Disable branch prediction"
	depends on CPU_ARM1020 || CPU_V6 || CPU_V6K || CPU_MOHAWK || CPU_XSC3 || CPU_V7 || CPU_FA526 || CPU_V7M
	help
	  Say Y here to disable branch prediction.  If unsure, say N.

config CPU_SPECTRE
	bool
	select GENERIC_CPU_VULNERABILITIES

config HARDEN_BRANCH_PREDICTOR
	bool "Harden the branch predictor against aliasing attacks" if EXPERT
	depends on CPU_SPECTRE
	default y
	help
	   Speculation attacks against some high-performance processors rely
	   on being able to manipulate the branch predictor for a victim
	   context by executing aliasing branches in the attacker context.
	   Such attacks can be partially mitigated against by clearing
	   internal branch predictor state and limiting the prediction
	   logic in some situations.

	   This config option will take CPU-specific actions to harden
	   the branch predictor against aliasing attacks and may rely on
	   specific instruction sequences or control bits being set by
	   the system firmware.

	   If unsure, say Y.

config HARDEN_BRANCH_HISTORY
	bool "Harden Spectre style attacks against branch history" if EXPERT
	depends on CPU_SPECTRE
	default y
	help
	  Speculation attacks against some high-performance processors can
	  make use of branch history to influence future speculation. When
	  taking an exception, a sequence of branches overwrites the branch
	  history, or branch history is invalidated.

config TLS_REG_EMUL
	bool
	select NEED_KUSER_HELPERS
	help
	  An SMP system using a pre-ARMv6 processor (there are apparently
	  a few prototypes like that in existence) and therefore access to
	  that required register must be emulated.

config NEED_KUSER_HELPERS
	bool

config KUSER_HELPERS
	bool "Enable kuser helpers in vector page" if !NEED_KUSER_HELPERS
	depends on MMU
	default y
	help
	  Warning: disabling this option may break user programs.

	  Provide kuser helpers in the vector page.  The kernel provides
	  helper code to userspace in read only form at a fixed location
	  in the high vector page to allow userspace to be independent of
	  the CPU type fitted to the system.  This permits binaries to be
	  run on ARMv4 through to ARMv7 without modification.

	  See Documentation/arch/arm/kernel_user_helpers.rst for details.

	  However, the fixed address nature of these helpers can be used
	  by ROP (return orientated programming) authors when creating
	  exploits.

	  If all of the binaries and libraries which run on your platform
	  are built specifically for your platform, and make no use of
	  these helpers, then you can turn this option off to hinder
	  such exploits. However, in that case, if a binary or library
	  relying on those helpers is run, it will receive a SIGILL signal,
	  which will terminate the program.

	  Say N here only if you are absolutely certain that you do not
	  need these helpers; otherwise, the safe option is to say Y.

config VDSO
	bool "Enable VDSO for acceleration of some system calls"
	depends on AEABI && MMU && CPU_V7
	default y if ARM_ARCH_TIMER
	select HAVE_GENERIC_VDSO
	select GENERIC_TIME_VSYSCALL
	select GENERIC_VDSO_32
	select GENERIC_GETTIMEOFDAY
	help
	  Place in the process address space an ELF shared object
	  providing fast implementations of gettimeofday and
	  clock_gettime.  Systems that implement the ARM architected
	  timer will receive maximum benefit.

	  You must have glibc 2.22 or later for programs to seamlessly
	  take advantage of this.


config OUTER_CACHE
	bool

config OUTER_CACHE_SYNC
	bool
	select ARM_HEAVY_MB
	help
	  The outer cache has a outer_cache_fns.sync function pointer
	  that can be used to drain the write buffer of the outer cache.

config CACHE_B15_RAC
	bool "Enable the Broadcom Brahma-B15 read-ahead cache controller"
	depends on ARCH_BRCMSTB
	default y
	help
	  This option enables the Broadcom Brahma-B15 read-ahead cache
	  controller. If disabled, the read-ahead cache remains off.

config CACHE_FEROCEON_L2
	bool "Enable the Feroceon L2 cache controller"
	depends on ARCH_MV78XX0 || ARCH_MVEBU
	default y
	select OUTER_CACHE
	help
	  This option enables the Feroceon L2 cache controller.

config CACHE_FEROCEON_L2_WRITETHROUGH
	bool "Force Feroceon L2 cache write through"
	depends on CACHE_FEROCEON_L2
	help
	  Say Y here to use the Feroceon L2 cache in writethrough mode.
	  Unless you specifically require this, say N for writeback mode.

config MIGHT_HAVE_CACHE_L2X0
	bool
	help
	  This option should be selected by machines which have a L2x0
	  or PL310 cache controller, but where its use is optional.

	  The only effect of this option is to make CACHE_L2X0 and
	  related options available to the user for configuration.

	  Boards or SoCs which always require the cache controller
	  support to be present should select CACHE_L2X0 directly
	  instead of this option, thus preventing the user from
	  inadvertently configuring a broken kernel.

config CACHE_L2X0
	bool "Enable the L2x0 outer cache controller" if MIGHT_HAVE_CACHE_L2X0
	default MIGHT_HAVE_CACHE_L2X0
	select OUTER_CACHE
	select OUTER_CACHE_SYNC
	help
	  This option enables the L2x0 PrimeCell.

config CACHE_L2X0_PMU
	bool "L2x0 performance monitor support" if CACHE_L2X0
	depends on PERF_EVENTS
	help
	  This option enables support for the performance monitoring features
	  of the L220 and PL310 outer cache controllers.

if CACHE_L2X0

config PL310_ERRATA_588369
	bool "PL310 errata: Clean & Invalidate maintenance operations do not invalidate clean lines"
	help
	   The PL310 L2 cache controller implements three types of Clean &
	   Invalidate maintenance operations: by Physical Address
	   (offset 0x7F0), by Index/Way (0x7F8) and by Way (0x7FC).
	   They are architecturally defined to behave as the execution of a
	   clean operation followed immediately by an invalidate operation,
	   both performing to the same memory location. This functionality
	   is not correctly implemented in PL310 prior to r2p0 (fixed in r2p0)
	   as clean lines are not invalidated as a result of these operations.

config PL310_ERRATA_727915
	bool "PL310 errata: Background Clean & Invalidate by Way operation can cause data corruption"
	help
	  PL310 implements the Clean & Invalidate by Way L2 cache maintenance
	  operation (offset 0x7FC). This operation runs in background so that
	  PL310 can handle normal accesses while it is in progress. Under very
	  rare circumstances, due to this erratum, write data can be lost when
	  PL310 treats a cacheable write transaction during a Clean &
	  Invalidate by Way operation.  Revisions prior to r3p1 are affected by
	  this errata (fixed in r3p1).

config PL310_ERRATA_753970
	bool "PL310 errata: cache sync operation may be faulty"
	help
	  This option enables the workaround for the 753970 PL310 (r3p0) erratum.

	  Under some condition the effect of cache sync operation on
	  the store buffer still remains when the operation completes.
	  This means that the store buffer is always asked to drain and
	  this prevents it from merging any further writes. The workaround
	  is to replace the normal offset of cache sync operation (0x730)
	  by another offset targeting an unmapped PL310 register 0x740.
	  This has the same effect as the cache sync operation: store buffer
	  drain and waiting for all buffers empty.

config PL310_ERRATA_769419
	bool "PL310 errata: no automatic Store Buffer drain"
	help
	  On revisions of the PL310 prior to r3p2, the Store Buffer does
	  not automatically drain. This can cause normal, non-cacheable
	  writes to be retained when the memory system is idle, leading
	  to suboptimal I/O performance for drivers using coherent DMA.
	  This option adds a write barrier to the cpu_idle loop so that,
	  on systems with an outer cache, the store buffer is drained
	  explicitly.

endif

config CACHE_TAUROS2
	bool "Enable the Tauros2 L2 cache controller"
	depends on (CPU_MOHAWK || CPU_PJ4)
	default y
	select OUTER_CACHE
	help
	  This option enables the Tauros2 L2 cache controller (as
	  found on PJ1/PJ4).

config CACHE_UNIPHIER
	bool "Enable the UniPhier outer cache controller"
	depends on ARCH_UNIPHIER
	select ARM_L1_CACHE_SHIFT_7
	select OUTER_CACHE
	select OUTER_CACHE_SYNC
	help
	  This option enables the UniPhier outer cache (system cache)
	  controller.

config CACHE_XSC3L2
	bool "Enable the L2 cache on XScale3"
	depends on CPU_XSC3
	default y
	select OUTER_CACHE
	help
	  This option enables the L2 cache on XScale3.

config ARM_L1_CACHE_SHIFT_6
	bool
	default y if CPU_V7
	help
	  Setting ARM L1 cache line size to 64 Bytes.

config ARM_L1_CACHE_SHIFT_7
	bool
	help
	  Setting ARM L1 cache line size to 128 Bytes.

config ARM_L1_CACHE_SHIFT
	int
	default 7 if ARM_L1_CACHE_SHIFT_7
	default 6 if ARM_L1_CACHE_SHIFT_6
	default 5

config ARM_DMA_MEM_BUFFERABLE
	bool "Use non-cacheable memory for DMA" if (CPU_V6 || CPU_V6K || CPU_V7M) && !CPU_V7
	default y if CPU_V6 || CPU_V6K || CPU_V7 || CPU_V7M
	help
	  Historically, the kernel has used strongly ordered mappings to
	  provide DMA coherent memory.  With the advent of ARMv7, mapping
	  memory with differing types results in unpredictable behaviour,
	  so on these CPUs, this option is forced on.

	  Multiple mappings with differing attributes is also unpredictable
	  on ARMv6 CPUs, but since they do not have aggressive speculative
	  prefetch, no harm appears to occur.

	  However, drivers may be missing the necessary barriers for ARMv6,
	  and therefore turning this on may result in unpredictable driver
	  behaviour.  Therefore, we offer this as an option.

	  On some of the beefier ARMv7-M machines (with DMA and write
	  buffers) you likely want this enabled, while those that
	  didn't need it until now also won't need it in the future.

	  You are recommended say 'Y' here and debug any affected drivers.

config ARM_HEAVY_MB
	bool

config DEBUG_ALIGN_RODATA
	bool "Make rodata strictly non-executable"
	depends on STRICT_KERNEL_RWX
	default y
	help
	  If this is set, rodata will be made explicitly non-executable. This
	  provides protection on the rare chance that attackers might find and
	  use ROP gadgets that exist in the rodata section. This adds an
	  additional section-aligned split of rodata from kernel text so it
	  can be made explicitly non-executable. This padding may waste memory
	  space to gain the additional protection.