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/*
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* SPDX - FileCopyrightText : 2022 Espressif Systems ( Shanghai ) CO LTD
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*
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* SPDX - License - Identifier : Apache - 2.0
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*/
# include "sdkconfig.h"
# include <stdint.h>
# include <string.h>
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# include "FreeRTOS.h"
# include "task.h" //For vApplicationStackOverflowHook
# include "portmacro.h"
# include "spinlock.h"
# include "xt_instr_macros.h"
# include "xtensa/xtensa_context.h"
# include "xtensa/corebits.h"
# include "xtensa/config/core.h"
# include "xtensa/config/core-isa.h"
# include "xtensa/xtruntime.h"
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# include "esp_private/esp_int_wdt.h"
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# include "esp_private/systimer.h"
# include "esp_private/periph_ctrl.h"
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# include "esp_attr.h"
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# include "esp_heap_caps.h"
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# include "esp_system.h"
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# include "esp_task.h"
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# include "esp_log.h"
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# include "esp_cpu.h"
# include "esp_rom_sys.h"
# include "esp_task_wdt.h"
# include "esp_heap_caps_init.h"
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# include "esp_freertos_hooks.h"
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# include "esp_intr_alloc.h"
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# include "esp_memory_utils.h"
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# ifdef CONFIG_FREERTOS_SYSTICK_USES_SYSTIMER
# include "soc/periph_defs.h"
# include "soc/system_reg.h"
# include "hal/systimer_hal.h"
# include "hal/systimer_ll.h"
# endif // CONFIG_FREERTOS_SYSTICK_USES_SYSTIMER
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_Static_assert ( portBYTE_ALIGNMENT = = 16 , " portBYTE_ALIGNMENT must be set to 16 " ) ;
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/*
OS state variables
*/
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volatile unsigned port_xSchedulerRunning [ portNUM_PROCESSORS ] = { 0 } ; // Indicates whether scheduler is running on a per-core basis
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unsigned int port_interruptNesting [ portNUM_PROCESSORS ] = { 0 } ; // Interrupt nesting level. Increased/decreased in portasm.c, _frxt_int_enter/_frxt_int_exit
//FreeRTOS SMP Locks
portMUX_TYPE port_xTaskLock = portMUX_INITIALIZER_UNLOCKED ;
portMUX_TYPE port_xISRLock = portMUX_INITIALIZER_UNLOCKED ;
/* ------------------------------------------------ IDF Compatibility --------------------------------------------------
* - These need to be defined for IDF to compile
* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
// --------------------- Interrupts ------------------------
BaseType_t IRAM_ATTR xPortInterruptedFromISRContext ( void )
{
return ( port_interruptNesting [ xPortGetCoreID ( ) ] ! = 0 ) ;
}
// ------------------ Critical Sections --------------------
/*
Variables used by IDF critical sections only ( SMP tracks critical nesting inside TCB now )
[ refactor - todo ] Figure out how IDF critical sections will be merged with SMP FreeRTOS critical sections
*/
BaseType_t port_uxCriticalNestingIDF [ portNUM_PROCESSORS ] = { 0 } ;
BaseType_t port_uxCriticalOldInterruptStateIDF [ portNUM_PROCESSORS ] = { 0 } ;
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/*
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* Interrupt stack . The size of the interrupt stack is determined by the config
* parameter " configISR_STACK_SIZE " in FreeRTOSConfig . h
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
*/
volatile StackType_t DRAM_ATTR __attribute__ ( ( aligned ( 16 ) ) ) port_IntStack [ portNUM_PROCESSORS ] [ configISR_STACK_SIZE ] ;
/* One flag for each individual CPU. */
volatile uint32_t port_switch_flag [ portNUM_PROCESSORS ] ;
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BaseType_t xPortEnterCriticalTimeout ( portMUX_TYPE * lock , BaseType_t timeout )
{
/* Interrupts may already be disabled (if this function is called in nested
* manner ) . However , there ' s no atomic operation that will allow us to check ,
* thus we have to disable interrupts again anyways .
*
* However , if this is call is NOT nested ( i . e . , the first call to enter a
* critical section ) , we will save the previous interrupt level so that the
* saved level can be restored on the last call to exit the critical .
*/
BaseType_t xOldInterruptLevel = XTOS_SET_INTLEVEL ( XCHAL_EXCM_LEVEL ) ;
if ( ! spinlock_acquire ( lock , timeout ) ) {
//Timed out attempting to get spinlock. Restore previous interrupt level and return
XTOS_RESTORE_JUST_INTLEVEL ( ( int ) xOldInterruptLevel ) ;
return pdFAIL ;
}
//Spinlock acquired. Increment the IDF critical nesting count.
BaseType_t coreID = xPortGetCoreID ( ) ;
BaseType_t newNesting = port_uxCriticalNestingIDF [ coreID ] + 1 ;
port_uxCriticalNestingIDF [ coreID ] = newNesting ;
//If this is the first entry to a critical section. Save the old interrupt level.
if ( newNesting = = 1 ) {
port_uxCriticalOldInterruptStateIDF [ coreID ] = xOldInterruptLevel ;
}
return pdPASS ;
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}
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void vPortExitCriticalIDF ( portMUX_TYPE * lock )
{
/* This function may be called in a nested manner. Therefore, we only need
* to reenable interrupts if this is the last call to exit the critical . We
* can use the nesting count to determine whether this is the last exit call .
*/
spinlock_release ( lock ) ;
BaseType_t coreID = xPortGetCoreID ( ) ;
BaseType_t nesting = port_uxCriticalNestingIDF [ coreID ] ;
if ( nesting > 0 ) {
nesting - - ;
port_uxCriticalNestingIDF [ coreID ] = nesting ;
//This is the last exit call, restore the saved interrupt level
if ( nesting = = 0 ) {
XTOS_RESTORE_JUST_INTLEVEL ( ( int ) port_uxCriticalOldInterruptStateIDF [ coreID ] ) ;
}
}
}
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/*
In case any IDF libs called the port critical functions directly instead of through the macros .
Just inline call the IDF versions
*/
void vPortEnterCritical ( portMUX_TYPE * lock )
{
vPortEnterCriticalIDF ( lock ) ;
}
void vPortExitCritical ( portMUX_TYPE * lock )
{
vPortExitCriticalIDF ( lock ) ;
}
// ----------------------- System --------------------------
# define STACK_WATCH_POINT_NUMBER (SOC_CPU_WATCHPOINTS_NUM - 1)
void vPortSetStackWatchpoint ( void * pxStackStart )
{
//Set watchpoint 1 to watch the last 32 bytes of the stack.
//Unfortunately, the Xtensa watchpoints can't set a watchpoint on a random [base - base+n] region because
//the size works by masking off the lowest address bits. For that reason, we futz a bit and watch the lowest 32
//bytes of the stack we can actually watch. In general, this can cause the watchpoint to be triggered at most
//28 bytes early. The value 32 is chosen because it's larger than the stack canary, which in FreeRTOS is 20 bytes.
//This way, we make sure we trigger before/when the stack canary is corrupted, not after.
int addr = ( int ) pxStackStart ;
addr = ( addr + 31 ) & ( ~ 31 ) ;
esp_cpu_set_watchpoint ( STACK_WATCH_POINT_NUMBER , ( char * ) addr , 32 , ESP_CPU_WATCHPOINT_STORE ) ;
}
// ---------------------- Tick Timer -----------------------
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BaseType_t xPortSysTickHandler ( void ) ;
# ifdef CONFIG_FREERTOS_SYSTICK_USES_CCOUNT
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extern void _frxt_tick_timer_init ( void ) ;
extern void _xt_tick_divisor_init ( void ) ;
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# ifdef CONFIG_FREERTOS_CORETIMER_0
# define SYSTICK_INTR_ID (ETS_INTERNAL_TIMER0_INTR_SOURCE+ETS_INTERNAL_INTR_SOURCE_OFF)
# endif
# ifdef CONFIG_FREERTOS_CORETIMER_1
# define SYSTICK_INTR_ID (ETS_INTERNAL_TIMER1_INTR_SOURCE+ETS_INTERNAL_INTR_SOURCE_OFF)
# endif
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/**
* @ brief Initialize CCONT timer to generate the tick interrupt
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*
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*/
void vPortSetupTimer ( void )
{
/* Init the tick divisor value */
_xt_tick_divisor_init ( ) ;
_frxt_tick_timer_init ( ) ;
}
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# elif CONFIG_FREERTOS_SYSTICK_USES_SYSTIMER
_Static_assert ( SOC_CPU_CORES_NUM < = SOC_SYSTIMER_ALARM_NUM - 1 , " the number of cores must match the number of core alarms in SYSTIMER " ) ;
void SysTickIsrHandler ( void * arg ) ;
static uint32_t s_handled_systicks [ portNUM_PROCESSORS ] = { 0 } ;
# define SYSTICK_INTR_ID (ETS_SYSTIMER_TARGET0_EDGE_INTR_SOURCE)
/**
* @ brief Set up the systimer peripheral to generate the tick interrupt
*
* Both timer alarms are configured in periodic mode .
* It is done at the same time so SysTicks for both CPUs occur at the same time or very close .
* Shifts a time of triggering interrupts for core 0 and core 1.
*/
void vPortSetupTimer ( void )
{
unsigned cpuid = xPortGetCoreID ( ) ;
# ifdef CONFIG_FREERTOS_CORETIMER_SYSTIMER_LVL3
const unsigned level = ESP_INTR_FLAG_LEVEL3 ;
# else
const unsigned level = ESP_INTR_FLAG_LEVEL1 ;
# endif
/* Systimer HAL layer object */
static systimer_hal_context_t systimer_hal ;
/* set system timer interrupt vector */
ESP_ERROR_CHECK ( esp_intr_alloc ( ETS_SYSTIMER_TARGET0_EDGE_INTR_SOURCE + cpuid , ESP_INTR_FLAG_IRAM | level , SysTickIsrHandler , & systimer_hal , NULL ) ) ;
if ( cpuid = = 0 ) {
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periph_module_enable ( PERIPH_SYSTIMER_MODULE ) ;
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systimer_hal_init ( & systimer_hal ) ;
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systimer_hal_tick_rate_ops_t ops = {
. ticks_to_us = systimer_ticks_to_us ,
. us_to_ticks = systimer_us_to_ticks ,
} ;
systimer_hal_set_tick_rate_ops ( & systimer_hal , & ops ) ;
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systimer_ll_set_counter_value ( systimer_hal . dev , SYSTIMER_LL_COUNTER_OS_TICK , 0 ) ;
systimer_ll_apply_counter_value ( systimer_hal . dev , SYSTIMER_LL_COUNTER_OS_TICK ) ;
for ( cpuid = 0 ; cpuid < SOC_CPU_CORES_NUM ; cpuid + + ) {
systimer_hal_counter_can_stall_by_cpu ( & systimer_hal , SYSTIMER_LL_COUNTER_OS_TICK , cpuid , false ) ;
}
for ( cpuid = 0 ; cpuid < portNUM_PROCESSORS ; + + cpuid ) {
uint32_t alarm_id = SYSTIMER_LL_ALARM_OS_TICK_CORE0 + cpuid ;
/* configure the timer */
systimer_hal_connect_alarm_counter ( & systimer_hal , alarm_id , SYSTIMER_LL_COUNTER_OS_TICK ) ;
systimer_hal_set_alarm_period ( & systimer_hal , alarm_id , 1000000UL / CONFIG_FREERTOS_HZ ) ;
systimer_hal_select_alarm_mode ( & systimer_hal , alarm_id , SYSTIMER_ALARM_MODE_PERIOD ) ;
systimer_hal_counter_can_stall_by_cpu ( & systimer_hal , SYSTIMER_LL_COUNTER_OS_TICK , cpuid , true ) ;
if ( cpuid = = 0 ) {
systimer_hal_enable_alarm_int ( & systimer_hal , alarm_id ) ;
systimer_hal_enable_counter ( & systimer_hal , SYSTIMER_LL_COUNTER_OS_TICK ) ;
# ifndef CONFIG_FREERTOS_UNICORE
// SysTick of core 0 and core 1 are shifted by half of period
systimer_hal_counter_value_advance ( & systimer_hal , SYSTIMER_LL_COUNTER_OS_TICK , 1000000UL / CONFIG_FREERTOS_HZ / 2 ) ;
# endif
}
}
} else {
uint32_t alarm_id = SYSTIMER_LL_ALARM_OS_TICK_CORE0 + cpuid ;
systimer_hal_enable_alarm_int ( & systimer_hal , alarm_id ) ;
}
}
/**
* @ brief Systimer interrupt handler .
*
* The Systimer interrupt for SysTick works in periodic mode no need to calc the next alarm .
* If a timer interrupt is ever serviced more than one tick late , it is necessary to process multiple ticks .
*/
IRAM_ATTR void SysTickIsrHandler ( void * arg )
{
uint32_t cpuid = xPortGetCoreID ( ) ;
systimer_hal_context_t * systimer_hal = ( systimer_hal_context_t * ) arg ;
# ifdef CONFIG_PM_TRACE
ESP_PM_TRACE_ENTER ( TICK , cpuid ) ;
# endif
uint32_t alarm_id = SYSTIMER_LL_ALARM_OS_TICK_CORE0 + cpuid ;
do {
systimer_ll_clear_alarm_int ( systimer_hal - > dev , alarm_id ) ;
uint32_t diff = systimer_hal_get_counter_value ( systimer_hal , SYSTIMER_LL_COUNTER_OS_TICK ) / systimer_ll_get_alarm_period ( systimer_hal - > dev , alarm_id ) - s_handled_systicks [ cpuid ] ;
if ( diff > 0 ) {
if ( s_handled_systicks [ cpuid ] = = 0 ) {
s_handled_systicks [ cpuid ] = diff ;
diff = 1 ;
} else {
s_handled_systicks [ cpuid ] + = diff ;
}
do {
xPortSysTickHandler ( ) ;
} while ( - - diff ) ;
}
} while ( systimer_ll_is_alarm_int_fired ( systimer_hal - > dev , alarm_id ) ) ;
# ifdef CONFIG_PM_TRACE
ESP_PM_TRACE_EXIT ( TICK , cpuid ) ;
# endif
}
# endif // CONFIG_FREERTOS_SYSTICK_USES_CCOUNT
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/* ---------------------------------------------- Port Implementations -------------------------------------------------
* Implementations of Porting Interface functions
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* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
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// --------------------- Interrupts ------------------------
BaseType_t xPortCheckIfInISR ( void )
{
//Disable interrupts so that reading port_interruptNesting is atomic
BaseType_t ret ;
unsigned int prev_int_level = portDISABLE_INTERRUPTS ( ) ;
ret = ( port_interruptNesting [ xPortGetCoreID ( ) ] ! = 0 ) ? pdTRUE : pdFALSE ;
portRESTORE_INTERRUPTS ( prev_int_level ) ;
return ret ;
}
// ------------------ Critical Sections --------------------
void vPortTakeLock ( portMUX_TYPE * lock )
{
spinlock_acquire ( lock , portMUX_NO_TIMEOUT ) ;
}
void vPortReleaseLock ( portMUX_TYPE * lock )
{
spinlock_release ( lock ) ;
}
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// ---------------------- Yielding -------------------------
// ----------------------- System --------------------------
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/* ------------------------------------------------ FreeRTOS Portable --------------------------------------------------
* - Provides implementation for functions required by FreeRTOS
* - Declared in portable . h
* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */
// ----------------- Scheduler Start/End -------------------
extern void _xt_coproc_init ( void ) ;
BaseType_t xPortStartScheduler ( void )
{
portDISABLE_INTERRUPTS ( ) ;
// Interrupts are disabled at this point and stack contains PS with enabled interrupts when task context is restored
# if XCHAL_CP_NUM > 0
/* Initialize co-processor management for tasks. Leave CPENABLE alone. */
_xt_coproc_init ( ) ;
# endif
/* Setup the hardware to generate the tick. */
vPortSetupTimer ( ) ;
port_xSchedulerRunning [ xPortGetCoreID ( ) ] = 1 ;
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# if configNUM_CORES > 1
// Workaround for non-thread safe multi-core OS startup (see IDF-4524)
if ( xPortGetCoreID ( ) ! = 0 ) {
vTaskStartSchedulerOtherCores ( ) ;
}
# endif // configNUM_CORES > 1
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// Cannot be directly called from C; never returns
__asm__ volatile ( " call0 _frxt_dispatch \n " ) ;
/* Should not get here. */
return pdTRUE ;
}
void vPortEndScheduler ( void )
{
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;
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}
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// ----------------------- Memory --------------------------
# define FREERTOS_SMP_MALLOC_CAPS (MALLOC_CAP_INTERNAL|MALLOC_CAP_8BIT)
void * pvPortMalloc ( size_t xSize )
{
return heap_caps_malloc ( xSize , FREERTOS_SMP_MALLOC_CAPS ) ;
}
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void vPortFree ( void * pv )
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{
heap_caps_free ( pv ) ;
}
void vPortInitialiseBlocks ( void )
{
; //Does nothing, heap is initialized separately in ESP-IDF
}
size_t xPortGetFreeHeapSize ( void )
{
return esp_get_free_heap_size ( ) ;
}
# if( configSTACK_ALLOCATION_FROM_SEPARATE_HEAP == 1 )
void * pvPortMallocStack ( size_t xSize )
{
return NULL ;
}
void vPortFreeStack ( void * pv )
{
}
# endif
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// ------------------------ Stack --------------------------
// User exception dispatcher when exiting
void _xt_user_exit ( void ) ;
# if CONFIG_FREERTOS_TASK_FUNCTION_WRAPPER
// Wrapper to allow task functions to return (increases stack overhead by 16 bytes)
static void vPortTaskWrapper ( TaskFunction_t pxCode , void * pvParameters )
{
pxCode ( pvParameters ) ;
//FreeRTOS tasks should not return. Log the task name and abort.
char * pcTaskName = pcTaskGetName ( NULL ) ;
ESP_LOGE ( " FreeRTOS " , " FreeRTOS Task \" %s \" should not return, Aborting now! " , pcTaskName ) ;
abort ( ) ;
}
# endif
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const DRAM_ATTR uint32_t offset_pxEndOfStack = offsetof ( StaticTask_t , pxDummy8 ) ;
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# if ( configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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const DRAM_ATTR uint32_t offset_uxCoreAffinityMask = offsetof ( StaticTask_t , uxDummy25 ) ;
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# endif // ( configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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const DRAM_ATTR uint32_t offset_cpsa = XT_CP_SIZE ;
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/**
* @ brief Align stack pointer in a downward growing stack
*
* This macro is used to round a stack pointer downwards to the nearest n - byte boundary , where n is a power of 2.
* This macro is generally used when allocating aligned areas on a downward growing stack .
*/
# define STACKPTR_ALIGN_DOWN(n, ptr) ((ptr) & (~((n)-1)))
# if XCHAL_CP_NUM > 0
/**
* @ brief Allocate and initialize coprocessor save area on the stack
*
* This function allocates the coprocessor save area on the stack ( sized XT_CP_SIZE ) which includes . . .
* - Individual save areas for each coprocessor ( size XT_CPx_SA , inclusive of each area ' s alignment )
* - Coprocessor context switching flags ( e . g . , XT_CPENABLE , XT_CPSTORED , XT_CP_CS_ST , XT_CP_ASA ) .
*
* The coprocessor save area is aligned to a 16 - byte boundary .
* The coprocessor context switching flags are then initialized
*
* @ param [ in ] uxStackPointer Current stack pointer address
* @ return Stack pointer that points to allocated and initialized the coprocessor save area
*/
FORCE_INLINE_ATTR UBaseType_t uxInitialiseStackCPSA ( UBaseType_t uxStackPointer )
{
/*
HIGH ADDRESS
| - - - - - - - - - - - - - - - - - - - | XT_CP_SIZE
| CPn SA | ^
| . . . | |
| CP0 SA | |
| - - - - - - - - - - - - - - - - - | | - - - - XCHAL_TOTAL_SA_ALIGN aligned
| - - - - - - - - - - - - - - - - - - - | | 12 bytes
| XT_CP_ASA | | ^
| XT_CP_CS_ST | | |
| XT_CPSTORED | | |
| XT_CPENABLE | | |
| - - - - - - - - - - - - - - - - - - - | - - - - - - - - - - - - - - - - - - - - - - 16 byte aligned
LOW ADDRESS
*/
// Allocate overall coprocessor save area, aligned down to 16 byte boundary
uxStackPointer = STACKPTR_ALIGN_DOWN ( 16 , uxStackPointer - XT_CP_SIZE ) ;
// Initialize the coprocessor context switching flags.
uint32_t * p = ( uint32_t * ) uxStackPointer ;
p [ 0 ] = 0 ; // Clear XT_CPENABLE and XT_CPSTORED
p [ 1 ] = 0 ; // Clear XT_CP_CS_ST
// XT_CP_ASA points to the aligned start of the individual CP save areas (i.e., start of CP0 SA)
p [ 2 ] = ( uint32_t ) ALIGNUP ( XCHAL_TOTAL_SA_ALIGN , ( uint32_t ) uxStackPointer + 12 ) ;
return uxStackPointer ;
}
# endif /* XCHAL_CP_NUM > 0 */
/**
* @ brief Allocate and initialize GCC TLS area
*
* This function allocates and initializes the area on the stack used to store GCC TLS ( Thread Local Storage ) variables .
* - The area ' s size is derived from the TLS section ' s linker variables , and rounded up to a multiple of 16 bytes
* - The allocated area is aligned to a 16 - byte aligned address
* - The TLS variables in the area are then initialized
*
* Each task access the TLS variables using the THREADPTR register plus an offset to obtain the address of the variable .
* The value for the THREADPTR register is also calculated by this function , and that value should be use to initialize
* the THREADPTR register .
*
* @ param [ in ] uxStackPointer Current stack pointer address
* @ param [ out ] ret_threadptr_reg_init Calculated THREADPTR register initialization value
* @ return Stack pointer that points to the TLS area
*/
FORCE_INLINE_ATTR UBaseType_t uxInitialiseStackTLS ( UBaseType_t uxStackPointer , uint32_t * ret_threadptr_reg_init )
{
/*
TLS layout at link - time , where 0 xNNN is the offset that the linker calculates to a particular TLS variable .
LOW ADDRESS
| - - - - - - - - - - - - - - - - - - - - - - - - - - - | Linker Symbols
| Section | - - - - - - - - - - - - - -
| . flash . rodata |
0x0 | - - - - - - - - - - - - - - - - - - - - - - - - - - - | < - _flash_rodata_start
^ | Other Data |
| | - - - - - - - - - - - - - - - - - - - - - - - - - - - | < - _thread_local_start
| | . tbss | ^
V | | |
0 xNNN | int example ; | | tls_area_size
| | |
| . tdata | V
| - - - - - - - - - - - - - - - - - - - - - - - - - - - | < - _thread_local_end
| Other data |
| . . . |
| - - - - - - - - - - - - - - - - - - - - - - - - - - - |
HIGH ADDRESS
*/
// Calculate the TLS area's size (rounded up to multiple of 16 bytes).
extern int _thread_local_start , _thread_local_end , _flash_rodata_start , _flash_rodata_align ;
const uint32_t tls_area_size = ALIGNUP ( 16 , ( uint32_t ) & _thread_local_end - ( uint32_t ) & _thread_local_start ) ;
// TODO: check that TLS area fits the stack
// Allocate space for the TLS area on the stack. The area must be allocated at a 16-byte aligned address
uxStackPointer = STACKPTR_ALIGN_DOWN ( 16 , uxStackPointer - ( UBaseType_t ) tls_area_size ) ;
// Initialize the TLS area with the initialization values of each TLS variable
memcpy ( ( void * ) uxStackPointer , & _thread_local_start , tls_area_size ) ;
/*
Calculate the THREADPTR register ' s initialization value based on the link - time offset and the TLS area allocated on
the stack .
HIGH ADDRESS
| - - - - - - - - - - - - - - - - - - - - - - - - - - - |
| . tdata ( * ) |
^ | int example ; |
| | |
| | . tbss ( * ) |
| | - - - - - - - - - - - - - - - - - - - - - - - - - - - | < - uxStackPointer ( start of TLS area )
0 xNNN | | | ^
| | | |
| . . . | ( _thread_local_start - _flash_rodata_start ) + align_up ( TCB_SIZE , tls_section_alignment )
| | | |
| | | V
V | | < - threadptr register ' s value
LOW ADDRESS
Note : Xtensa is slightly different compared to the RISC - V port as there is an implicit aligned TCB_SIZE added to
the offset . ( search for ' tpoff ' in elf32 - xtensa . c in BFD ) :
- " offset = address - tls_section_vma + align_up(TCB_SIZE, tls_section_alignment) "
- TCB_SIZE is hardcoded to 8
*/
const uint32_t tls_section_align = ( uint32_t ) & _flash_rodata_align ; // ALIGN value of .flash.rodata section
# define TCB_SIZE 8
const uint32_t base = ALIGNUP ( tls_section_align , TCB_SIZE ) ;
* ret_threadptr_reg_init = ( uint32_t ) uxStackPointer - ( ( uint32_t ) & _thread_local_start - ( uint32_t ) & _flash_rodata_start ) - base ;
return uxStackPointer ;
}
/**
* @ brief Initialize the task ' s starting interrupt stack frame
*
* This function initializes the task ' s starting interrupt stack frame . The dispatcher will use this stack frame in a
* context restore routine . Therefore , the starting stack frame must be initialized as if the task was interrupted right
* before its first instruction is called .
*
* - The stack frame is allocated to a 16 - byte aligned address
* - The THREADPTR register is saved in the extra storage area of the stack frame . This is also initialized
*
* @ param [ in ] uxStackPointer Current stack pointer address
* @ param [ in ] pxCode Task function
* @ param [ in ] pvParameters Task function ' s parameter
* @ param [ in ] threadptr_reg_init THREADPTR register initialization value
* @ return Stack pointer that points to the stack frame
*/
FORCE_INLINE_ATTR UBaseType_t uxInitialiseStackFrame ( UBaseType_t uxStackPointer , TaskFunction_t pxCode , void * pvParameters , uint32_t threadptr_reg_init )
{
/*
HIGH ADDRESS
| - - - - - - - - - - - - - - - - - - - - - - - - - - - | ^ XT_STK_FRMSZ
| | |
| Stack Frame Extra Storage | |
| | |
| - - - - - - - - - - - - - - - - - - - - - - - - - | | ^ XT_STK_EXTRA
| | | |
| Intr / Exc Stack Frame | | |
| | V V
| - - - - - - - - - - - - - - - - - - - - - - - - - | - - - - - - - - - - - - - - - - - - - - - - 16 byte aligned
LOW ADDRESS
*/
/*
Allocate space for the task ' s starting interrupt stack frame .
- The stack frame must be allocated to a 16 - byte aligned address .
- We use XT_STK_FRMSZ ( instead of sizeof ( XtExcFrame ) ) as it . . .
- includes the size of the extra storage area
- includes the size for a base save area before the stack frame
- rounds up the total size to a multiple of 16
*/
UBaseType_t uxStackPointerPrevious = uxStackPointer ;
uxStackPointer = STACKPTR_ALIGN_DOWN ( 16 , uxStackPointer - XT_STK_FRMSZ ) ;
// Clear the entire interrupt stack frame
memset ( ( void * ) uxStackPointer , 0 , ( size_t ) ( uxStackPointerPrevious - uxStackPointer ) ) ;
XtExcFrame * frame = ( XtExcFrame * ) uxStackPointer ;
/*
Initialize common registers
*/
frame - > a0 = 0 ; // Set the return address to 0 terminate GDB backtrace
frame - > a1 = uxStackPointer + XT_STK_FRMSZ ; // Saved stack pointer should point to physical top of stack frame
frame - > exit = ( UBaseType_t ) _xt_user_exit ; // User exception exit dispatcher
/*
Initialize the task ' s entry point . This will differ depending on
- Whether the task ' s entry point is the wrapper function or pxCode
- Whether Windowed ABI is used ( for windowed , we mimic the task entry point being call4 ' d )
*/
# if CONFIG_FREERTOS_TASK_FUNCTION_WRAPPER
frame - > pc = ( UBaseType_t ) vPortTaskWrapper ; // Task entry point is the wrapper function
# ifdef __XTENSA_CALL0_ABI__
frame - > a2 = ( UBaseType_t ) pxCode ; // Wrapper function's argument 0 (which is the task function)
frame - > a3 = ( UBaseType_t ) pvParameters ; // Wrapper function's argument 1 (which is the task function's argument)
# else // __XTENSA_CALL0_ABI__
frame - > a6 = ( UBaseType_t ) pxCode ; // Wrapper function's argument 0 (which is the task function), passed as if we call4'd
frame - > a7 = ( UBaseType_t ) pvParameters ; // Wrapper function's argument 1 (which is the task function's argument), passed as if we call4'd
# endif // __XTENSA_CALL0_ABI__
# else
frame - > pc = ( UBaseType_t ) pxCode ; // Task entry point is the provided task function
# ifdef __XTENSA_CALL0_ABI__
frame - > a2 = ( UBaseType_t ) pvParameters ; // Task function's argument
# else // __XTENSA_CALL0_ABI__
frame - > a6 = ( UBaseType_t ) pvParameters ; // Task function's argument, passed as if we call4'd
# endif // __XTENSA_CALL0_ABI__
# endif
/*
Set initial PS to int level 0 , EXCM disabled ( ' rfe ' will enable ) , user mode .
For windowed ABI also set WOE and CALLINC ( pretend task was ' call4 ' d )
*/
# ifdef __XTENSA_CALL0_ABI__
frame - > ps = PS_UM | PS_EXCM ;
# else // __XTENSA_CALL0_ABI__
frame - > ps = PS_UM | PS_EXCM | PS_WOE | PS_CALLINC ( 1 ) ;
# endif // __XTENSA_CALL0_ABI__
# ifdef XT_USE_SWPRI
// Set the initial virtual priority mask value to all 1's.
frame - > vpri = 0xFFFFFFFF ;
# endif
// Initialize the threadptr register in the extra save area of the stack frame
uint32_t * threadptr_reg = ( uint32_t * ) ( uxStackPointer + XT_STK_EXTRA ) ;
* threadptr_reg = threadptr_reg_init ;
return uxStackPointer ;
}
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# if ( portHAS_STACK_OVERFLOW_CHECKING == 1 )
StackType_t * pxPortInitialiseStack ( StackType_t * pxTopOfStack ,
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StackType_t * pxEndOfStack ,
TaskFunction_t pxCode ,
void * pvParameters )
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# else
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StackType_t * pxPortInitialiseStack ( StackType_t * pxTopOfStack ,
TaskFunction_t pxCode ,
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void * pvParameters )
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# endif
{
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/*
HIGH ADDRESS
| - - - - - - - - - - - - - - - - - - - - - - - - - - - | < - pxTopOfStack on entry
| Coproc Save Area |
| - - - - - - - - - - - - - - - - - - - - - - - - - |
| TLS Variables |
| - - - - - - - - - - - - - - - - - - - - - - - - - | < - Start of useable stack
| Starting stack frame |
| - - - - - - - - - - - - - - - - - - - - - - - - - | < - pxTopOfStack on return ( which is the tasks current SP )
| | |
| | |
| V |
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - < - Bottom of stack
LOW ADDRESS
- All stack areas are aligned to 16 byte boundary
- We use UBaseType_t for all of stack area initialization functions for more convenient pointer arithmetic
*/
UBaseType_t uxStackPointer = ( UBaseType_t ) pxTopOfStack ;
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configASSERT ( ( uxStackPointer & portBYTE_ALIGNMENT_MASK ) = = 0 ) ;
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# if XCHAL_CP_NUM > 0
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// Initialize the coprocessor save area
uxStackPointer = uxInitialiseStackCPSA ( uxStackPointer ) ;
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configASSERT ( ( uxStackPointer & portBYTE_ALIGNMENT_MASK ) = = 0 ) ;
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# endif /* XCHAL_CP_NUM > 0 */
// Initialize the GCC TLS area
uint32_t threadptr_reg_init ;
uxStackPointer = uxInitialiseStackTLS ( uxStackPointer , & threadptr_reg_init ) ;
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configASSERT ( ( uxStackPointer & portBYTE_ALIGNMENT_MASK ) = = 0 ) ;
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// Initialize the starting interrupt stack frame
uxStackPointer = uxInitialiseStackFrame ( uxStackPointer , pxCode , pvParameters , threadptr_reg_init ) ;
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configASSERT ( ( uxStackPointer & portBYTE_ALIGNMENT_MASK ) = = 0 ) ;
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// Return the task's current stack pointer address which should point to the starting interrupt stack frame
return ( StackType_t * ) uxStackPointer ;
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}
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// -------------------- Co-Processor -----------------------
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# if ( XCHAL_CP_NUM > 0 && configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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void _xt_coproc_release ( volatile void * coproc_sa_base , BaseType_t xCoreID ) ;
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void vPortCleanUpCoprocArea ( void * pxTCB )
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{
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StackType_t * coproc_area ;
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BaseType_t xCoreID ;
/* Calculate the coproc save area in the stack from the TCB base */
coproc_area = ( StackType_t * ) ( ( uint32_t ) ( pxTCB + offset_pxEndOfStack ) ) ;
coproc_area = ( StackType_t * ) ( ( ( portPOINTER_SIZE_TYPE ) coproc_area ) & ( ~ ( ( portPOINTER_SIZE_TYPE ) portBYTE_ALIGNMENT_MASK ) ) ) ;
coproc_area = ( StackType_t * ) ( ( ( uint32_t ) coproc_area - XT_CP_SIZE ) & ~ 0xf ) ;
/* Extract core ID from the affinity mask */
xCoreID = __builtin_ffs ( * ( UBaseType_t * ) ( pxTCB + offset_uxCoreAffinityMask ) ) ;
assert ( xCoreID > = 1 ) ;
xCoreID - = 1 ;
/* If task has live floating point registers somewhere, release them */
_xt_coproc_release ( coproc_area , xCoreID ) ;
}
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# endif // ( XCHAL_CP_NUM > 0 && configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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// ------- Thread Local Storage Pointers Deletion Callbacks -------
# if ( CONFIG_FREERTOS_TLSP_DELETION_CALLBACKS )
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void vPortTLSPointersDelCb ( void * pxTCB )
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{
/* Typecast pxTCB to StaticTask_t type to access TCB struct members.
* pvDummy15 corresponds to pvThreadLocalStoragePointers member of the TCB .
*/
StaticTask_t * tcb = ( StaticTask_t * ) pxTCB ;
/* The TLSP deletion callbacks are stored at an offset of (configNUM_THREAD_LOCAL_STORAGE_POINTERS/2) */
TlsDeleteCallbackFunction_t * pvThreadLocalStoragePointersDelCallback = ( TlsDeleteCallbackFunction_t * ) ( & ( tcb - > pvDummy15 [ ( configNUM_THREAD_LOCAL_STORAGE_POINTERS / 2 ) ] ) ) ;
/* We need to iterate over half the depth of the pvThreadLocalStoragePointers area
* to access all TLS pointers and their respective TLS deletion callbacks .
*/
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for ( int x = 0 ; x < ( configNUM_THREAD_LOCAL_STORAGE_POINTERS / 2 ) ; x + + ) {
if ( pvThreadLocalStoragePointersDelCallback [ x ] ! = NULL ) { //If del cb is set
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/* In case the TLSP deletion callback has been overwritten by a TLS pointer, gracefully abort. */
if ( ! esp_ptr_executable ( pvThreadLocalStoragePointersDelCallback [ x ] ) ) {
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// We call EARLY log here as currently portCLEAN_UP_TCB() is called in a critical section
ESP_EARLY_LOGE ( " FreeRTOS " , " Fatal error: TLSP deletion callback at index %d overwritten with non-excutable pointer %p " , x , pvThreadLocalStoragePointersDelCallback [ x ] ) ;
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abort ( ) ;
}
pvThreadLocalStoragePointersDelCallback [ x ] ( x , tcb - > pvDummy15 [ x ] ) ; //Call del cb
}
}
}
# endif // CONFIG_FREERTOS_TLSP_DELETION_CALLBACKS
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// -------------------- Tick Handler -----------------------
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extern void esp_vApplicationIdleHook ( void ) ;
extern void esp_vApplicationTickHook ( void ) ;
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BaseType_t xPortSysTickHandler ( void )
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{
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portbenchmarkIntLatency ( ) ;
traceISR_ENTER ( SYSTICK_INTR_ID ) ;
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BaseType_t ret ;
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esp_vApplicationTickHook ( ) ;
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if ( portGET_CORE_ID ( ) = = 0 ) {
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// FreeRTOS SMP requires that only core 0 calls xTaskIncrementTick()
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ret = xTaskIncrementTick ( ) ;
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} else {
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ret = pdFALSE ;
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}
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if ( ret ! = pdFALSE ) {
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portYIELD_FROM_ISR ( ) ;
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} else {
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traceISR_EXIT ( ) ;
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}
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return ret ;
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}
// ------------------- Hook Functions ----------------------
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# include <stdlib.h>
# if ( configCHECK_FOR_STACK_OVERFLOW > 0 )
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void __attribute__ ( ( weak ) ) vApplicationStackOverflowHook ( TaskHandle_t xTask , char * pcTaskName )
{
# define ERR_STR1 "***ERROR*** A stack overflow in task "
# define ERR_STR2 " has been detected."
const char * str [ ] = { ERR_STR1 , pcTaskName , ERR_STR2 } ;
char buf [ sizeof ( ERR_STR1 ) + CONFIG_FREERTOS_MAX_TASK_NAME_LEN + sizeof ( ERR_STR2 ) + 1 /* null char */ ] = { 0 } ;
char * dest = buf ;
for ( size_t i = 0 ; i < sizeof ( str ) / sizeof ( str [ 0 ] ) ; i + + ) {
dest = strcat ( dest , str [ i ] ) ;
}
esp_system_abort ( buf ) ;
}
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# endif
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# if CONFIG_FREERTOS_USE_MINIMAL_IDLE_HOOK
/*
By default , the port uses vApplicationMinimalIdleHook ( ) to run IDF style idle
hooks . However , users may also want to provide their own vApplicationMinimalIdleHook ( ) .
In this case , we use to - Wl , - - wrap option to wrap the user provided vApplicationMinimalIdleHook ( )
*/
extern void __real_vApplicationMinimalIdleHook ( void ) ;
void __wrap_vApplicationMinimalIdleHook ( void )
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{
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esp_vApplicationIdleHook ( ) ; //Run IDF style hooks
__real_vApplicationMinimalIdleHook ( ) ; //Call the user provided vApplicationMinimalIdleHook()
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}
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# else // CONFIG_FREERTOS_USE_MINIMAL_IDLE_HOOK
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void vApplicationMinimalIdleHook ( void )
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{
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esp_vApplicationIdleHook ( ) ; //Run IDF style hooks
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}
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# endif // CONFIG_FREERTOS_USE_MINIMAL_IDLE_HOOK
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/*
* Hook function called during prvDeleteTCB ( ) to cleanup any
* user defined static memory areas in the TCB .
*/
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# if CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP
void __real_vPortCleanUpTCB ( void * pxTCB ) ;
void __wrap_vPortCleanUpTCB ( void * pxTCB )
# else
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void vPortCleanUpTCB ( void * pxTCB )
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# endif /* CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP */
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{
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# if ( CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP )
/* Call user defined vPortCleanUpTCB */
__real_vPortCleanUpTCB ( pxTCB ) ;
# endif /* CONFIG_FREERTOS_ENABLE_STATIC_TASK_CLEAN_UP */
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# if ( CONFIG_FREERTOS_TLSP_DELETION_CALLBACKS )
/* Call TLS pointers deletion callbacks */
vPortTLSPointersDelCb ( pxTCB ) ;
# endif /* CONFIG_FREERTOS_TLSP_DELETION_CALLBACKS */
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# if ( XCHAL_CP_NUM > 0 && configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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/* Cleanup coproc save area */
vPortCleanUpCoprocArea ( pxTCB ) ;
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# endif // ( XCHAL_CP_NUM > 0 && configUSE_CORE_AFFINITY == 1 && configNUM_CORES > 1 )
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}