/*
ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010 Giovanni Di Sirio.
This file is part of ChibiOS/RT.
ChibiOS/RT is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
ChibiOS/RT is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
/**
* @defgroup ARMCMx ARM Cortex-Mx
* @details This port supports the ARM Cortex-Mx architectures, specifically
* the Cortex-M0 and the Cortex-M3.
*
* @section ARMCMx_STATES Mapping of the System States in the ARM Cortex-Mx port
* The ChibiOS/RT logical @ref system_states are mapped as follow in the ARM
* Cortex-Mx port:
* - Init. This state is represented by the startup code and the
* initialization code before @p chSysInit() is executed. It has not a
* special hardware state associated.
* - Normal. This is the state the system has after executing
* @p chSysInit(). In this state the ARM Cortex-Mx has the BASEPRI register
* set at @p CORTEX_BASEPRI_USER level, interrupts are not masked. The
* processor is running in thread-privileged mode.
* - Suspended. In this state the interrupt sources are not globally
* masked but the BASEPRI register is set to @p CORTEX_BASEPRI_KERNEL thus
* masking any interrupt source with lower or equal priority. The processor
* is running in thread-privileged mode.
* - Disabled. Interrupt sources are globally masked. The processor
* is running in thread-privileged mode.
* - Sleep. This state is entered with the execution of the specific
* instruction @p wfi.
* - S-Locked. In this state the interrupt sources are not globally
* masked but the BASEPRI register is set to @p CORTEX_BASEPRI_KERNEL thus
* masking any interrupt source with lower or equal priority. The processor
* is running in thread-privileged mode.
* - I-Locked. In this state the interrupt sources are not globally
* masked but the BASEPRI register is set to @p CORTEX_BASEPRI_KERNEL thus
* masking any interrupt source with lower or equal priority. The processor
* is running in exception-privileged mode.
* - Serving Regular Interrupt. In this state the interrupt sources are
* not globally masked but only interrupts with higher priority can preempt
* the current handler. The processor is running in exception-privileged mode.
* - Serving Fast Interrupt. It is basically the same of the SRI state
* but it is not possible to switch to the I-Locked state because fast
* interrupts can preempt the kernel critical zone.
* - Serving Non-Maskable Interrupt. The Cortex-Mx has a specific
* asynchronous NMI vector and several synchronous fault vectors that can
* be considered to be in this category.
* - Halted. Implemented as an infinite loop after globally masking all
* the maskable interrupt sources. The ARM state is whatever the processor
* was running when @p chSysHalt() was invoked.
* .
* @section ARMCMx_NOTES The ARM Cortex-Mx port notes
* The ARM Cortex-Mx port is organized as follow:
* - The @p main() function is invoked in thread-privileged mode.
* - Each thread has a private process stack, the system has a single main
* stack where all the interrupts and exceptions are processed.
* - Only the 4 MSb of the priority level are used, the 4 LSb are assumed
* to be zero.
* - The threads are started in thread-privileged mode with BASEPRI level
* 0x00 (disabled).
* - The kernel raises its BASEPRI level to @p CORTEX_BASEPRI_KERNEL in order
* to protect the kernel data structures.
* - Interrupt nesting and the other advanced NVIC features are supported.
* - The SVC instruction and vector, with parameter #0, is internally used
* for commanded context switching.
* It is possible to share the SVC handler at the cost of slower context
* switching.
* - The PendSV vector is internally used for preemption context switching.
* .
* @ingroup ports
*/
/**
* @defgroup ARMCMx_CONF Configuration Options
* @brief ARM Cortex-Mx Configuration Options.
* @details The ARMCMx port allows some architecture-specific configurations
* settings that can be specified externally, as example on the compiler
* command line:
* - @p INT_REQUIRED_STACK, this value represent the amount of stack space used
* by an interrupt handler between the @p extctx and @p intctx
* structures.
* In the current implementation this value is guaranteed to be zero so
* there is no need to modify this value unless changes are done at the
* interrupts handling code.
* - @p CORTEX_BASEPRI_USER, this is the @p BASEPRI value for the user threads.
* The default value is @p 0 (disabled).
* Usually there is no need to change this value, please refer to the
* Cortex-Mx technical reference manual for a detailed description.
* - @p CORTEX_BASEPRI_KERNEL, this is the @p BASEPRI value for the kernel lock
* code.
* Code running at higher priority levels must not invoke any OS API.
* Usually there is no need to change this value, please refer to the
* Cortex-Mx technical reference manual for a detailed description.
* - @p ENABLE_WFI_IDLE, if set to @p 1 enables the use of the @p wfi
* instruction from within the idle loop. This is defaulted to 0 because
* it can create problems with some debuggers. Setting this option to 1
* reduces the system power requirements.
* .
* @ingroup ARMCMx
*/
/**
* @defgroup ARMCMx_CORE Core Port Implementation
* @brief ARM Cortex-Mx specific port code, structures and macros.
*
* @ingroup ARMCMx
*/
/**
* @defgroup ARMCMx_STARTUP Startup Support
* @brief ARM Cortex-Mx startup code support.
* @details ChibiOS/RT provides its own generic startup file for the ARM
* Cortex-Mx port.
* Of course it is not mandatory to use it but care should be taken about the
* startup phase details.
*
* Startup Process
* The startup process, as implemented, is the following:
* -# Interrupts are masked globally.
* -# The two stacks are initialized by assigning them the sizes defined in the
* linker script (usually named @p ch.ld). Stack areas are allocated from
* the highest RAM location downward.
* -# An early initialization routine @p hwinit0 is invoked, if the symbol is
* not defined then an empty default routine is executed (weak symbol).
* -# DATA and BSS segments are initialized.
* -# The CPU state is switched to Privileged and the PSP stack is used.
* -# A late initialization routine @p hwinit1 is invoked, if the symbol not
* defined then an empty default routine is executed (weak symbol).
* This late initialization function is also the proper place for a
* @a bootloader, if your application requires one.
* -# The @p main() function is invoked with the parameters @p argc and @p argv
* set to zero.
* -# Should the @p main() function return a branch is performed to the weak
* symbol MainExitHandler. The default code is an endless empty loop.
* .
* Expected linker symbols
* The startup code starts at the symbol @p ResetHandler and expects the
* following symbols to be defined in the linker script:
* - @p __ram_end__ RAM end location +1.
* - @p __main_stack_size__ Exception stack size.
* - @p __process_stack_size__ Process stack size. This is the stack area used
* by the @p main() function.
* - @p _textdata address of the data segment source read only data.
* - @p _data data segment start location.
* - @p _edata data segment end location +1.
* - @p _bss_start BSS start location.
* - @p _bss_end BSS end location +1.
* .
* @ingroup ARMCMx
* @file ARMCMx/crt0.s Startup code.
*/
/**
* @defgroup ARMCMx_NVIC NVIC Support
* @brief ARM Cortex-Mx NVIC support.
*
* @ingroup ARMCMx
*/