zephyr/arch/arm/core/aarch32/Kconfig

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# ARM core configuration options
# Copyright (c) 2015 Wind River Systems, Inc.
# SPDX-License-Identifier: Apache-2.0
config CPU_CORTEX_M
bool
select CPU_CORTEX
select ARCH_HAS_CUSTOM_SWAP_TO_MAIN
select HAS_CMSIS_CORE
select HAS_FLASH_LOAD_OFFSET
select ARCH_HAS_SINGLE_THREAD_SUPPORT
select ARCH_HAS_THREAD_ABORT
select ARCH_HAS_TRUSTED_EXECUTION if ARM_TRUSTZONE_M
select ARCH_HAS_STACK_PROTECTION if (ARM_MPU && !ARMV6_M_ARMV8_M_BASELINE) || CPU_CORTEX_M_HAS_SPLIM
select ARCH_HAS_USERSPACE if ARM_MPU
select ARCH_HAS_NOCACHE_MEMORY_SUPPORT if ARM_MPU && CPU_HAS_ARM_MPU && CPU_CORTEX_M7
select ARCH_HAS_RAMFUNC_SUPPORT
select ARCH_HAS_NESTED_EXCEPTION_DETECTION
select SWAP_NONATOMIC
select ARCH_HAS_EXTRA_EXCEPTION_INFO
select ARCH_HAS_TIMING_FUNCTIONS if CPU_CORTEX_M_HAS_DWT
select ARCH_SUPPORTS_ARCH_HW_INIT
imply XIP
help
This option signifies the use of a CPU of the Cortex-M family.
config CPU_CORTEX_R
bool
select CPU_CORTEX
select HAS_CMSIS_CORE
select HAS_FLASH_LOAD_OFFSET
select ARCH_HAS_EXTRA_EXCEPTION_INFO
help
This option signifies the use of a CPU of the Cortex-R family.
config ISA_THUMB2
bool
help
From: http://www.arm.com/products/processors/technologies/instruction-set-architectures.php
Thumb-2 technology is the instruction set underlying the ARM Cortex
architecture which provides enhanced levels of performance, energy
efficiency, and code density for a wide range of embedded
applications.
Thumb-2 technology builds on the success of Thumb, the innovative
high code density instruction set for ARM microprocessor cores, to
increase the power of the ARM microprocessor core available to
developers of low cost, high performance systems.
The technology is backwards compatible with existing ARM and Thumb
solutions, while significantly extending the features available to
the Thumb instructions set. This allows more of the application to
benefit from the best in class code density of Thumb.
For performance optimized code Thumb-2 technology uses 31 percent
less memory to reduce system cost, while providing up to 38 percent
higher performance than existing high density code, which can be used
to prolong battery-life or to enrich the product feature set. Thumb-2
technology is featured in the processor, and in all ARMv7
architecture-based processors.
config ISA_ARM
bool
help
From: https://developer.arm.com/products/architecture/instruction-sets/a32-and-t32-instruction-sets
A32 instructions, known as Arm instructions in pre-Armv8 architectures,
are 32 bits wide, and are aligned on 4-byte boundaries. A32 instructions
are supported by both A-profile and R-profile architectures.
A32 was traditionally used in applications requiring the highest
performance, or for handling hardware exceptions such as interrupts and
processor start-up. Much of its functionality was subsumed into T32 with
the introduction of Thumb-2 technology.
config ASSEMBLER_ISA_THUMB2
bool
default y if ISA_THUMB2 && !ISA_ARM
depends on !ISA_ARM
help
This helper symbol specifies the default target instruction set for
the assembler.
When only the Thumb-2 ISA is supported (i.e. on Cortex-M cores), the
assembler must use the Thumb-2 instruction set.
When both the Thumb-2 and ARM ISAs are supported (i.e. on Cortex-A
and Cortex-R cores), the assembler must use the ARM instruction set
because the architecture assembly code makes use of the ARM
instructions.
config COMPILER_ISA_THUMB2
bool "Compile C/C++ functions using Thumb-2 instruction set"
depends on ISA_THUMB2
default y
help
This option configures the compiler to compile all C/C++ functions
using the Thumb-2 instruction set.
N.B. The scope of this symbol is not necessarily limited to the C and
C++ languages; in fact, this symbol refers to all forms of
"compiled" code.
When an additional natively-compiled language support is added
in the future, this symbol shall also specify the Thumb-2
instruction set for that language.
config NUM_IRQS
int
config STACK_ALIGN_DOUBLE_WORD
bool "Align stacks on double-words (8 octets)"
default y
help
This is needed to conform to AAPCS, the procedure call standard for
the ARM. It wastes stack space. The option also enforces alignment
of stack upon exception entry on Cortex-M3 and Cortex-M4 (ARMv7-M).
Note that for ARMv6-M, ARMv8-M, and Cortex-M7 MCUs stack alignment
on exception entry is enabled by default and it is not configurable.
config RUNTIME_NMI
bool "Attach an NMI handler at runtime"
select REBOOT
help
The kernel provides a simple NMI handler that simply hangs in a tight
loop if triggered. This fills the requirement that there must be an
NMI handler installed when the CPU boots. If a custom handler is
needed, enable this option and attach it via _NmiHandlerSet().
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).
config FAULT_DUMP
int "Fault dump level"
default 2
range 0 2
help
Different levels for display information when a fault occurs.
2: The default. Display specific and verbose information. Consumes
the most memory (long strings).
1: Display general and short information. Consumes less memory
(short strings).
0: Off.
config BUILTIN_STACK_GUARD
bool "Thread Stack Guards based on built-in ARM stack limit checking"
depends on CPU_CORTEX_M_HAS_SPLIM
select THREAD_STACK_INFO
help
Enable Thread/Interrupt Stack Guards via built-in Stack Pointer
limit checking. The functionality must be supported by HW.
config ARM_STACK_PROTECTION
bool
default y if HW_STACK_PROTECTION
imply BUILTIN_STACK_GUARD if CPU_CORTEX_M_HAS_SPLIM
select MPU_STACK_GUARD if (!BUILTIN_STACK_GUARD && ARM_MPU)
help
This option enables either:
- The built-in Stack Pointer limit checking, or
- the MPU-based stack guard
to cause a system fatal error
if the bounds of the current process stack are overflowed.
The two stack guard options are mutually exclusive. The
selection of the built-in Stack Pointer limit checking is
prioritized over the MPU-based stack guard. The developer
still has the option to manually select the MPU-based
stack guard, if this is desired.
config ARM_SECURE_FIRMWARE
bool
depends on ARMV8_M_SE
default y if TRUSTED_EXECUTION_SECURE
help
This option indicates that we are building a Zephyr image that
is intended to execute in Secure state. The option is only
applicable to ARMv8-M MCUs that implement the Security Extension.
This option enables Zephyr to include code that executes in
Secure state, as well as to exclude code that is designed to
execute only in Non-secure state.
Code executing in Secure state has access to both the Secure
and Non-Secure resources of the Cortex-M MCU.
Code executing in Non-Secure state may trigger Secure Faults,
if Secure MCU resources are accessed from the Non-Secure state.
Secure Faults may only be handled by code executing in Secure
state.
config ARM_NONSECURE_FIRMWARE
bool
depends on !ARM_SECURE_FIRMWARE
depends on ARMV8_M_SE
default y if TRUSTED_EXECUTION_NONSECURE
help
This option indicates that we are building a Zephyr image that
is intended to execute in Non-Secure state. Execution of this
image is triggered by Secure firmware that executes in Secure
state. The option is only applicable to ARMv8-M MCUs that
implement the Security Extension.
This option enables Zephyr to include code that executes in
Non-Secure state only, as well as to exclude code that is
designed to execute only in Secure state.
Code executing in Non-Secure state has no access to Secure
resources of the Cortex-M MCU, and, therefore, it shall avoid
accessing them.
config ARM_NONSECURE_PREEMPTIBLE_SECURE_CALLS
bool "Allow secure function calls to be preempted"
depends on ARM_NONSECURE_FIRMWARE
help
When enabled, this option indicates that preemptible Zephyr
threads performing secure function calls, are allowed to be
preempted. When disabled, the option indicates that such
threads many not be context-switched-out while doing a Secure
function call.
config ARM_STORE_EXC_RETURN
bool
default y if FPU_SHARING || ARM_NONSECURE_PREEMPTIBLE_SECURE_CALLS
help
Store the EXC_RETURN value when switching threads.
This is needed when switching between threads that differ in either
FPU usage or security domain.
choice
prompt "Floating point ABI"
default FP_HARDABI
depends on FPU
config FP_HARDABI
bool "Floating point Hard ABI"
depends on !BUILD_WITH_TFM
help
This option selects the Floating point ABI in which hardware floating
point instructions are generated and uses FPU-specific calling
conventions.
Note: the option is disabled for Zephyr builds with TF-M, as TF-M
does not currently support building with Hard ABI, hence linking
Zephyr with TF-M libraries would not be possible.
config FP_SOFTABI
bool "Floating point Soft ABI"
help
This option selects the Floating point ABI in which hardware floating
point instructions are generated but soft-float calling conventions.
endchoice
rsource "cortex_m/Kconfig"
rsource "cortex_a_r/Kconfig"
rsource "mpu/Kconfig"