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