arch/arm/core/cortex_m/Kconfig - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 # ARM Cortex-M platform configuration options

 # Copyright (c) 2014-2015 Wind River Systems, Inc.
 # SPDX-License-Identifier: Apache-2.0

 # NOTE: We have the specific core implementations first and outside of the
 # if CPU_CORTEX_M block so that SoCs can select which core they are using
 # without having to select all the options related to that core.  Everything
 # else is captured inside the if CPU_CORTEX_M block so they are not exposed
 # if one select a differnet ARM Cortex Family (Cortex-A or Cortex-R)

 config CPU_CORTEX_M0
 	bool
 	select CPU_CORTEX_M
 	select ARMV6_M_ARMV8_M_BASELINE
 	help
 	  This option signifies the use of a Cortex-M0 CPU

 config CPU_CORTEX_M0PLUS
 	bool
 	select CPU_CORTEX_M
 	select ARMV6_M_ARMV8_M_BASELINE
 	help
 	  This option signifies the use of a Cortex-M0+ CPU

 config CPU_CORTEX_M3
 	bool
 	select CPU_CORTEX_M
 	select ARMV7_M_ARMV8_M_MAINLINE
 	help
 	  This option signifies the use of a Cortex-M3 CPU

 config CPU_CORTEX_M4
 	bool
 	select CPU_CORTEX_M
 	select ARMV7_M_ARMV8_M_MAINLINE
 	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
 	help
 	  This option signifies the use of a Cortex-M4 CPU

 config CPU_CORTEX_M23
 	bool
 	select CPU_CORTEX_M
 	select ARMV8_M_BASELINE
 	select ARMV8_M_SE if CPU_HAS_TEE
 	help
 	  This option signifies the use of a Cortex-M23 CPU

 config CPU_CORTEX_M33
 	bool
 	select CPU_CORTEX_M
 	select ARMV8_M_MAINLINE
 	select ARMV8_M_SE if CPU_HAS_TEE
 	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
 	help
 	  This option signifies the use of a Cortex-M33 CPU

 config CPU_CORTEX_M7
 	bool
 	select CPU_CORTEX_M
 	select ARMV7_M_ARMV8_M_MAINLINE
 	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
 	help
 	  This option signifies the use of a Cortex-M7 CPU

 if CPU_CORTEX_M

 config CPU_CORTEX_M_HAS_SYSTICK
 	bool
 	help
 	  This option is enabled when the CPU implements the SysTick timer.

 config CPU_CORTEX_M_HAS_BASEPRI
 	bool
 	depends on ARMV7_M_ARMV8_M_MAINLINE
 	help
 	  This option signifies the CPU has the BASEPRI register.

 	  The BASEPRI register defines the minimum priority for
 	  exception processing. When BASEPRI is set to a nonzero
 	  value, it prevents the activation of all exceptions with
 	  the same or lower priority level as the BASEPRI value.
 	  Always present in CPUs that implement the ARMv7-M or
 	  ARM8-M Mainline architectures.

 config CPU_CORTEX_M_HAS_VTOR
 	bool
 	depends on !CPU_CORTEX_M0
 	help
 	  This option signifies the CPU has the VTOR register.
 	  The VTOR indicates the offset of the vector table base
 	  address from memory address 0x00000000. Always present
 	  in CPUs implementing the ARMv7-M or ARMv8-M architectures.
 	  Optional in CPUs implementing ARMv6-M, ARMv8-M Baseline
 	  architectures (except for Cortex-M0, where it is never
 	  implemented).

 config CPU_CORTEX_M_HAS_SPLIM
 	bool
 	depends on ARMV8_M_MAINLINE || (ARMV8_M_SE && !ARM_NONSECURE_FIRMWARE)
 	help
 	  This option signifies the CPU has the MSPLIM, PSPLIM registers.

 	  The stack pointer limit registers, MSPLIM, PSPLIM, limit the
 	  extend to which the Main and Process Stack Pointers, respectively,
 	  can descend. MSPLIM, PSPLIM are always present in ARMv8-M
 	  MCUs that implement the ARMv8-M Main Extension (Mainline).

 	  In an ARMv8-M Mainline implementation with the Security Extension
 	  the MSPLIM, PSPLIM registers have additional Secure instances.
 	  In an ARMv8-M Baseline implementation with the Security Extension
 	  the MSPLIM, PSPLIM registers have only Secure instances.

 config CPU_CORTEX_M_HAS_PROGRAMMABLE_FAULT_PRIOS
 	bool
 	depends on ARMV7_M_ARMV8_M_MAINLINE
 	help
 	  This option signifies the CPU may trigger system faults
 	  (other than HardFault) with configurable priority, and,
 	  therefore, it needs to reserve a priority level for them.

 config CPU_CORTEX_M0_HAS_VECTOR_TABLE_REMAP
 	bool
 	help
 	  This option signifies the Cortex-M0 has some mechanisms that can map
 	  the vector table to SRAM

 config CPU_CORTEX_M_HAS_CMSE
 	bool
 	depends on ARMV8_M_BASELINE || ARMV8_M_MAINLINE
 	help
 	  This option signifies the Cortex-M CPU has the CMSE intrinsics.

 config ARMV6_M_ARMV8_M_BASELINE
 	bool
 	select ATOMIC_OPERATIONS_C
 	select ISA_THUMB2
 	help
 	  This option signifies the use of an ARMv6-M processor
 	  implementation, or the use of an ARMv8-M processor
 	  supporting the Baseline implementation.

 	  Notes:
 	  - A Processing Element (PE) without the Main Extension
 	  is also referred to as a Baseline Implementation. A
 	  Baseline implementation has a subset of the instructions,
 	  registers, and features, of a Mainline implementation.
 	  - ARMv6-M compatibility is provided by all ARMv8-M
 	  implementations.

 config ARMV8_M_BASELINE
 	bool
 	select ARMV6_M_ARMV8_M_BASELINE
 	select CPU_CORTEX_M_HAS_CMSE
 	help
 	  This option signifies the use of an ARMv8-M processor
 	  implementation.

 	  ARMv8-M Baseline includes additional features
 	  not present in the ARMv6-M architecture.

 config ARMV7_M_ARMV8_M_MAINLINE
 	bool
 	select ATOMIC_OPERATIONS_BUILTIN
 	select ISA_THUMB2
 	select CPU_CORTEX_M_HAS_BASEPRI
 	select CPU_CORTEX_M_HAS_VTOR
 	select CPU_CORTEX_M_HAS_PROGRAMMABLE_FAULT_PRIOS
 	select CPU_CORTEX_M_HAS_SYSTICK
 	help
 	  This option signifies the use of an ARMv7-M processor
 	  implementation, or the use of a backwards-compatible
 	  ARMv8-M processor implementation supporting the Main
 	  Extension.

 	  Notes:
 	  - A Processing Element (PE) with the Main Extension is also
 	  referred to as a Mainline Implementation.
 	  - ARMv7-M compatibility requires the Main Extension.

 	  From https://developer.arm.com/products/architecture/m-profile:
 	  The Main Extension provides backwards compatibility
 	  with ARMv7-M.

 config ARMV8_M_MAINLINE
 	bool
 	select ARMV7_M_ARMV8_M_MAINLINE
 	select CPU_CORTEX_M_HAS_SPLIM
 	select CPU_CORTEX_M_HAS_CMSE
 	help
 	  This option signifies the use of an ARMv8-M processor
 	  implementation, supporting the Main Extension.

 	  ARMv8-M Main Extension includes additional features
 	  not present in the ARMv7-M architecture.

 config ARMV8_M_SE
 	bool
 	depends on ARMV8_M_BASELINE || ARMV8_M_MAINLINE
 	select CPU_CORTEX_M_HAS_SPLIM if !ARM_NONSECURE_FIRMWARE
 	help
 	  This option signifies the use of an ARMv8-M processor
 	  implementation (Baseline or Mainline) supporting the
 	  Security Extensions.

 config ARMV7_M_ARMV8_M_FP
 	bool
 	depends on ARMV7_M_ARMV8_M_MAINLINE && !CPU_CORTEX_M3
 	help
 	  This option signifies the use of an ARMv7-M processor
 	  implementation, or the use of an ARMv8-M processor
 	  implementation supporting the Floating-Point Extension.

 config ARMV8_M_DSP
 	bool
 	depends on ARMV8_M_MAINLINE
 	help
 	  This option signifies the use of an ARMv8-M processor
 	  implementation supporting the DSP Extension.

 config XIP
 	default y

 menu "ARM Cortex-M0/M0+/M3/M4/M7/M23/M33 options"
     depends on ARMV6_M_ARMV8_M_BASELINE || ARMV7_M_ARMV8_M_MAINLINE

 config GEN_ISR_TABLES
 	default y

 config ZERO_LATENCY_IRQS
 	bool "Enable zero-latency interrupts"
 	depends on CPU_CORTEX_M_HAS_BASEPRI
 	help
 	  The kernel may reserve some of the highest interrupts priorities in
 	  the system for its own use. These interrupts will not be masked
 	  by interrupt locking.
 	  When connecting interrupts the kernel will offset all interrupts
 	  to lower priority than those reserved by the kernel.
 	  Zero-latency interrupt can be used to set up an interrupt at the
 	  highest interrupt priority which will not be blocked by interrupt
 	  locking.
 	  Since Zero-latency ISRs will run in the same priority or possibly at
 	  higher priority than the rest of the kernel they cannot use any
 	  kernel functionality.

 config SW_VECTOR_RELAY
 	bool "Enable Software Vector Relay"
 	default y if BOOTLOADER_MCUBOOT
 	depends on ARMV6_M_ARMV8_M_BASELINE && !(CPU_CORTEX_M0_HAS_VECTOR_TABLE_REMAP || CPU_CORTEX_M_HAS_VTOR)
 	help
 	  Add Vector Table relay handler and relay vector table, to
 	  relay interrupts based on a vector table pointer. This is only
 	  required for Cortex-M0 (or an Armv8-M baseline core) with no hardware
 	  vector table relocation mechanisms or for Cortex-M0+
 	  (or an Armv8-M baseline core) with no VTOR and no other hardware
 	  relocation table mechanisms.

 config PLATFORM_SPECIFIC_INIT
 	bool "Enable platform (SOC) specific startup hook"
 	help
 	  The platform specific initialization code (z_platform_init) is executed
 	  at the beginning of the startup code (__start).

 endmenu

 endif # CPU_CORTEX_M
	# ARM Cortex-M platform configuration options

	# Copyright (c) 2014-2015 Wind River Systems, Inc.
	# SPDX-License-Identifier: Apache-2.0

	# NOTE: We have the specific core implementations first and outside of the
	# if CPU_CORTEX_M block so that SoCs can select which core they are using
	# without having to select all the options related to that core. Everything
	# else is captured inside the if CPU_CORTEX_M block so they are not exposed
	# if one select a differnet ARM Cortex Family (Cortex-A or Cortex-R)

	config CPU_CORTEX_M0
	bool
	select CPU_CORTEX_M
	select ARMV6_M_ARMV8_M_BASELINE
	help
	This option signifies the use of a Cortex-M0 CPU

	config CPU_CORTEX_M0PLUS
	bool
	select CPU_CORTEX_M
	select ARMV6_M_ARMV8_M_BASELINE
	help
	This option signifies the use of a Cortex-M0+ CPU

	config CPU_CORTEX_M3
	bool
	select CPU_CORTEX_M
	select ARMV7_M_ARMV8_M_MAINLINE
	help
	This option signifies the use of a Cortex-M3 CPU

	config CPU_CORTEX_M4
	bool
	select CPU_CORTEX_M
	select ARMV7_M_ARMV8_M_MAINLINE
	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
	help
	This option signifies the use of a Cortex-M4 CPU

	config CPU_CORTEX_M23
	bool
	select CPU_CORTEX_M
	select ARMV8_M_BASELINE
	select ARMV8_M_SE if CPU_HAS_TEE
	help
	This option signifies the use of a Cortex-M23 CPU

	config CPU_CORTEX_M33
	bool
	select CPU_CORTEX_M
	select ARMV8_M_MAINLINE
	select ARMV8_M_SE if CPU_HAS_TEE
	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
	help
	This option signifies the use of a Cortex-M33 CPU

	config CPU_CORTEX_M7
	bool
	select CPU_CORTEX_M
	select ARMV7_M_ARMV8_M_MAINLINE
	select ARMV7_M_ARMV8_M_FP if CPU_HAS_FPU
	help
	This option signifies the use of a Cortex-M7 CPU

	if CPU_CORTEX_M

	config CPU_CORTEX_M_HAS_SYSTICK
	bool
	help
	This option is enabled when the CPU implements the SysTick timer.

	config CPU_CORTEX_M_HAS_BASEPRI
	bool
	depends on ARMV7_M_ARMV8_M_MAINLINE
	help
	This option signifies the CPU has the BASEPRI register.

	The BASEPRI register defines the minimum priority for
	exception processing. When BASEPRI is set to a nonzero
	value, it prevents the activation of all exceptions with
	the same or lower priority level as the BASEPRI value.
	Always present in CPUs that implement the ARMv7-M or
	ARM8-M Mainline architectures.

	config CPU_CORTEX_M_HAS_VTOR
	bool
	depends on !CPU_CORTEX_M0
	help
	This option signifies the CPU has the VTOR register.
	The VTOR indicates the offset of the vector table base
	address from memory address 0x00000000. Always present
	in CPUs implementing the ARMv7-M or ARMv8-M architectures.
	Optional in CPUs implementing ARMv6-M, ARMv8-M Baseline
	architectures (except for Cortex-M0, where it is never
	implemented).

	config CPU_CORTEX_M_HAS_SPLIM
	bool
	depends on ARMV8_M_MAINLINE \|\| (ARMV8_M_SE && !ARM_NONSECURE_FIRMWARE)
	help
	This option signifies the CPU has the MSPLIM, PSPLIM registers.

	The stack pointer limit registers, MSPLIM, PSPLIM, limit the
	extend to which the Main and Process Stack Pointers, respectively,
	can descend. MSPLIM, PSPLIM are always present in ARMv8-M
	MCUs that implement the ARMv8-M Main Extension (Mainline).

	In an ARMv8-M Mainline implementation with the Security Extension
	the MSPLIM, PSPLIM registers have additional Secure instances.
	In an ARMv8-M Baseline implementation with the Security Extension
	the MSPLIM, PSPLIM registers have only Secure instances.

	config CPU_CORTEX_M_HAS_PROGRAMMABLE_FAULT_PRIOS
	bool
	depends on ARMV7_M_ARMV8_M_MAINLINE
	help
	This option signifies the CPU may trigger system faults
	(other than HardFault) with configurable priority, and,
	therefore, it needs to reserve a priority level for them.

	config CPU_CORTEX_M0_HAS_VECTOR_TABLE_REMAP
	bool
	help
	This option signifies the Cortex-M0 has some mechanisms that can map
	the vector table to SRAM

	config CPU_CORTEX_M_HAS_CMSE
	bool
	depends on ARMV8_M_BASELINE \|\| ARMV8_M_MAINLINE
	help
	This option signifies the Cortex-M CPU has the CMSE intrinsics.

	config ARMV6_M_ARMV8_M_BASELINE
	bool
	select ATOMIC_OPERATIONS_C
	select ISA_THUMB2
	help
	This option signifies the use of an ARMv6-M processor
	implementation, or the use of an ARMv8-M processor
	supporting the Baseline implementation.

	Notes:
	- A Processing Element (PE) without the Main Extension
	is also referred to as a Baseline Implementation. A
	Baseline implementation has a subset of the instructions,
	registers, and features, of a Mainline implementation.
	- ARMv6-M compatibility is provided by all ARMv8-M
	implementations.

	config ARMV8_M_BASELINE
	bool
	select ARMV6_M_ARMV8_M_BASELINE
	select CPU_CORTEX_M_HAS_CMSE
	help
	This option signifies the use of an ARMv8-M processor
	implementation.

	ARMv8-M Baseline includes additional features
	not present in the ARMv6-M architecture.

	config ARMV7_M_ARMV8_M_MAINLINE
	bool
	select ATOMIC_OPERATIONS_BUILTIN
	select ISA_THUMB2
	select CPU_CORTEX_M_HAS_BASEPRI
	select CPU_CORTEX_M_HAS_VTOR
	select CPU_CORTEX_M_HAS_PROGRAMMABLE_FAULT_PRIOS
	select CPU_CORTEX_M_HAS_SYSTICK
	help
	This option signifies the use of an ARMv7-M processor
	implementation, or the use of a backwards-compatible
	ARMv8-M processor implementation supporting the Main
	Extension.

	Notes:
	- A Processing Element (PE) with the Main Extension is also
	referred to as a Mainline Implementation.
	- ARMv7-M compatibility requires the Main Extension.

	From https://developer.arm.com/products/architecture/m-profile:
	The Main Extension provides backwards compatibility
	with ARMv7-M.

	config ARMV8_M_MAINLINE
	bool
	select ARMV7_M_ARMV8_M_MAINLINE
	select CPU_CORTEX_M_HAS_SPLIM
	select CPU_CORTEX_M_HAS_CMSE
	help
	This option signifies the use of an ARMv8-M processor
	implementation, supporting the Main Extension.

	ARMv8-M Main Extension includes additional features
	not present in the ARMv7-M architecture.

	config ARMV8_M_SE
	bool
	depends on ARMV8_M_BASELINE \|\| ARMV8_M_MAINLINE
	select CPU_CORTEX_M_HAS_SPLIM if !ARM_NONSECURE_FIRMWARE
	help
	This option signifies the use of an ARMv8-M processor
	implementation (Baseline or Mainline) supporting the
	Security Extensions.

	config ARMV7_M_ARMV8_M_FP
	bool
	depends on ARMV7_M_ARMV8_M_MAINLINE && !CPU_CORTEX_M3
	help
	This option signifies the use of an ARMv7-M processor
	implementation, or the use of an ARMv8-M processor
	implementation supporting the Floating-Point Extension.

	config ARMV8_M_DSP
	bool
	depends on ARMV8_M_MAINLINE
	help
	This option signifies the use of an ARMv8-M processor
	implementation supporting the DSP Extension.

	config XIP
	default y

	menu "ARM Cortex-M0/M0+/M3/M4/M7/M23/M33 options"
	depends on ARMV6_M_ARMV8_M_BASELINE \|\| ARMV7_M_ARMV8_M_MAINLINE

	config GEN_ISR_TABLES
	default y

	config ZERO_LATENCY_IRQS
	bool "Enable zero-latency interrupts"
	depends on CPU_CORTEX_M_HAS_BASEPRI
	help
	The kernel may reserve some of the highest interrupts priorities in
	the system for its own use. These interrupts will not be masked
	by interrupt locking.
	When connecting interrupts the kernel will offset all interrupts
	to lower priority than those reserved by the kernel.
	Zero-latency interrupt can be used to set up an interrupt at the
	highest interrupt priority which will not be blocked by interrupt
	locking.
	Since Zero-latency ISRs will run in the same priority or possibly at
	higher priority than the rest of the kernel they cannot use any
	kernel functionality.

	config SW_VECTOR_RELAY
	bool "Enable Software Vector Relay"
	default y if BOOTLOADER_MCUBOOT
	depends on ARMV6_M_ARMV8_M_BASELINE && !(CPU_CORTEX_M0_HAS_VECTOR_TABLE_REMAP \|\| CPU_CORTEX_M_HAS_VTOR)
	help
	Add Vector Table relay handler and relay vector table, to
	relay interrupts based on a vector table pointer. This is only
	required for Cortex-M0 (or an Armv8-M baseline core) with no hardware
	vector table relocation mechanisms or for Cortex-M0+
	(or an Armv8-M baseline core) with no VTOR and no other hardware
	relocation table mechanisms.

	config PLATFORM_SPECIFIC_INIT
	bool "Enable platform (SOC) specific startup hook"
	help
	The platform specific initialization code (z_platform_init) is executed
	at the beginning of the startup code (__start).

	endmenu

	endif # CPU_CORTEX_M