zephyr/arch/arm64/core/Kconfig

354 lines
8.8 KiB
Plaintext

# ARM64 core configuration options
# Copyright (c) 2019 Carlo Caione <ccaione@baylibre.com>
# SPDX-License-Identifier: Apache-2.0
config CPU_CORTEX_A
bool
select CPU_CORTEX
select HAS_FLASH_LOAD_OFFSET
select SCHED_IPI_SUPPORTED if SMP
select CPU_HAS_FPU
select ARCH_HAS_SINGLE_THREAD_SUPPORT
select CPU_HAS_DCACHE
select CPU_HAS_ICACHE
imply FPU
imply FPU_SHARING
help
This option signifies the use of a CPU of the Cortex-A family.
config CPU_AARCH64_CORTEX_R
bool
select CPU_CORTEX
select HAS_FLASH_LOAD_OFFSET
select CPU_HAS_DCACHE
select CPU_HAS_ICACHE
select ARCH_HAS_STACK_PROTECTION
select CPU_HAS_FPU
imply FPU
imply FPU_SHARING
help
This option signifies the use of a CPU of the Cortex-R 64-bit family.
config CPU_CORTEX_A53
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A53 CPU
config CPU_CORTEX_A55
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A55 CPU
config CPU_CORTEX_A57
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A57 CPU
config CPU_CORTEX_A72
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A72 CPU
config CPU_CORTEX_A76
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A76 CPU
config CPU_CORTEX_A76_A55
bool
select CPU_CORTEX_A
select ARMV8_A
help
This option signifies the use of a Cortex-A76 and A55 big little CPU cluster
config CPU_CORTEX_R82
bool
select CPU_AARCH64_CORTEX_R
select ARMV8_R
help
This option signifies the use of a Cortex-R82 CPU
config HAS_ARM_SMCCC
bool
help
Include support for the Secure Monitor Call (SMC) and Hypervisor
Call (HVC) instructions on Armv7 and above architectures.
config NUM_IRQS
int
config MAIN_STACK_SIZE
default 4096
config IDLE_STACK_SIZE
default 4096
config ISR_STACK_SIZE
default 4096
config TEST_EXTRA_STACK_SIZE
default 2048
config SYSTEM_WORKQUEUE_STACK_SIZE
default 4096
config CMSIS_THREAD_MAX_STACK_SIZE
default 4096
config CMSIS_V2_THREAD_MAX_STACK_SIZE
default 4096
config CMSIS_V2_THREAD_DYNAMIC_STACK_SIZE
default 4096
config IPM_CONSOLE_STACK_SIZE
default 2048
config AARCH64_IMAGE_HEADER
bool "Add image header"
default y if ARM_MMU || ARM_MPU
help
This option enables standard ARM64 boot image header used by Linux
and understood by loaders such as u-boot on Xen xl tool.
config PRIVILEGED_STACK_SIZE
default 4096
config KOBJECT_TEXT_AREA
default 512 if TEST
config WAIT_AT_RESET_VECTOR
bool "Wait at reset vector"
default n
help
Spin at reset vector waiting for debugger to attach and resume
execution
config ARM64_SAFE_EXCEPTION_STACK
bool "To enable the safe exception stack"
help
The safe exception stack is used for checking whether the kernel stack
overflows during the exception happens from EL1. This stack is not
used for user stack overflow checking, because kernel stack support
the checking work.
config ARM64_ENABLE_FRAME_POINTER
bool
default y
depends on OVERRIDE_FRAME_POINTER_DEFAULT && !OMIT_FRAME_POINTER
help
Hidden option to simplify access to OVERRIDE_FRAME_POINTER_DEFAULT
and OMIT_FRAME_POINTER. It is automatically enabled when the frame
pointer unwinding is enabled.
config ARM64_SAFE_EXCEPTION_STACK_SIZE
int "The stack size of the safe exception stack"
default 4096
depends on ARM64_SAFE_EXCEPTION_STACK
help
The stack size of the safe exception stack. The safe exception stack
requires to be enough to do the stack overflow check.
config ARM64_FALLBACK_ON_RESERVED_CORES
bool "To enable fallback on reserved cores"
help
Give the ability to define more cores in the device tree than required
via CONFIG_MP_MAX_NUM_CPUS. The extra cores in the device tree
become reserved. If there is an issue powering on a core during boot
then that core will be skipped and the next core in the device tree
will be used.
config ARM64_STACK_PROTECTION
bool
default y if HW_STACK_PROTECTION
depends on ARM_MPU
select THREAD_STACK_INFO
select ARM64_SAFE_EXCEPTION_STACK
help
This option leverages the MMU or MPU to cause a system fatal error if
the bounds of the current process stack are overflowed. This is done
by preceding all stack areas with a fixed guard region.
if CPU_CORTEX_A
config ARMV8_A_NS
bool "ARMv8-A Normal World (Non-Secure world of Trustzone)"
help
This option signifies that Zephyr is entered in TrustZone
Non-Secure state
config ARMV8_A
bool
select ATOMIC_OPERATIONS_BUILTIN
select CPU_HAS_MMU
select ARCH_HAS_USERSPACE if ARM_MMU
select ARCH_HAS_NOCACHE_MEMORY_SUPPORT if ARM_MMU
help
This option signifies the use of an ARMv8-A processor
implementation.
From https://developer.arm.com/products/architecture/cpu-architecture/a-profile:
The Armv8-A architecture introduces the ability to use 64-bit and
32-bit Execution states, known as AArch64 and AArch32 respectively.
The AArch64 Execution state supports the A64 instruction set, holds
addresses in 64-bit registers and allows instructions in the base
instruction set to use 64-bit registers for their processing. The AArch32
Execution state is a 32-bit Execution state that preserves backwards
compatibility with the Armv7-A architecture and enhances that profile
so that it can support some features included in the AArch64 state.
It supports the T32 and A32 instruction sets.
rsource "xen/Kconfig"
endif # CPU_CORTEX_A
if CPU_AARCH64_CORTEX_R
config ARMV8_R
bool
select ATOMIC_OPERATIONS_BUILTIN
select SCHED_IPI_SUPPORTED if SMP
select ARCH_HAS_USERSPACE if ARM_MPU
help
This option signifies the use of an ARMv8-R processor
implementation.
From https://developer.arm.com/products/architecture/cpu-architecture/r-profile:
The Armv8-R architecture targets at the Real-time profile. It introduces
virtualization at the highest security level while retaining the
Protected Memory System Architecture (PMSA) based on a Memory Protection
Unit (MPU). It supports the A32 and T32 instruction sets.
rsource "cortex_r/Kconfig"
endif # CPU_AARCH64_CORTEX_R
if CPU_CORTEX_A || CPU_AARCH64_CORTEX_R
config GEN_ISR_TABLES
default y
config GEN_IRQ_VECTOR_TABLE
default n
config ARM_MMU
bool "ARM MMU Support"
default n if CPU_AARCH64_CORTEX_R
default y
select MMU
select SRAM_REGION_PERMISSIONS
select ARCH_MEM_DOMAIN_SYNCHRONOUS_API if USERSPACE
select ARCH_MEM_DOMAIN_DATA if USERSPACE
help
Memory Management Unit support.
config XIP
select AARCH64_IMAGE_HEADER
config ARM64_SET_VMPIDR_EL2
bool "Set VMPIDR_EL2 at EL2 stage"
help
VMPIDR_EL2 holds the value of the Virtualization Multiprocessor ID.
This is the value returned by EL1 reads of MPIDR_EL1.
This register may already be set by bootloader at the EL2 stage, if
not, Zephyr should set it.
if ARM_MMU
config MMU_PAGE_SIZE
default 0x1000
choice ARM64_VA_BITS
prompt "Virtual address space size"
default ARM64_VA_BITS_32
help
Allows choosing one of multiple possible virtual address
space sizes. The level of translation table is determined by
a combination of page size and virtual address space size.
config ARM64_VA_BITS_32
bool "32-bit"
config ARM64_VA_BITS_36
bool "36-bit"
config ARM64_VA_BITS_40
bool "40-bit"
config ARM64_VA_BITS_42
bool "42-bit"
config ARM64_VA_BITS_48
bool "48-bit"
endchoice
config ARM64_VA_BITS
int
default 32 if ARM64_VA_BITS_32
default 36 if ARM64_VA_BITS_36
default 40 if ARM64_VA_BITS_40
default 42 if ARM64_VA_BITS_42
default 48 if ARM64_VA_BITS_48
choice ARM64_PA_BITS
prompt "Physical address space size"
default ARM64_PA_BITS_32
help
Choose the maximum physical address range that the kernel will
support.
config ARM64_PA_BITS_32
bool "32-bit"
config ARM64_PA_BITS_36
bool "36-bit"
config ARM64_PA_BITS_40
bool "40-bit"
config ARM64_PA_BITS_42
bool "42-bit"
config ARM64_PA_BITS_48
bool "48-bit"
endchoice
config ARM64_PA_BITS
int
default 32 if ARM64_PA_BITS_32
default 36 if ARM64_PA_BITS_36
default 40 if ARM64_PA_BITS_40
default 42 if ARM64_PA_BITS_42
default 48 if ARM64_PA_BITS_48
config MAX_XLAT_TABLES
int "Maximum numbers of translation tables"
default 20 if USERSPACE && (ARM64_VA_BITS >= 40)
default 16 if USERSPACE
default 12 if (ARM64_VA_BITS >= 40)
default 8
help
This option specifies the maximum numbers of translation tables.
Based on this, translation tables are allocated at compile time and
used at runtime as needed. If the runtime need exceeds preallocated
numbers of translation tables, it will result in assert. Number of
translation tables required is decided based on how many discrete
memory regions (both normal and device memory) are present on given
platform and how much granularity is required while assigning
attributes to these memory regions.
endif # ARM_MMU
endif # CPU_CORTEX_A || CPU_AARCH64_CORTEX_R