/*This file has been prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
 *
 * \brief FreeRTOS port source for AVR32 UC3.
 *
 * - Compiler:           GNU GCC for AVR32
 * - Supported devices:  All AVR32 devices can be used.
 * - AppNote:
 *
 * \author               Atmel Corporation (Now Microchip):
 *                                        https://www.microchip.com \n
 *                       Support and FAQ: https://www.microchip.com/support/
 *
 *****************************************************************************/

/*
 * FreeRTOS Kernel V10.4.3
 * Copyright (C) 2020 Amazon.com, Inc. or its affiliates.  All Rights Reserved.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy of
 * this software and associated documentation files (the "Software"), to deal in
 * the Software without restriction, including without limitation the rights to
 * use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
 * the Software, and to permit persons to whom the Software is furnished to do so,
 * subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in all
 * copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
 * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
 * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
 * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 *
 * https://www.FreeRTOS.org
 * https://github.com/FreeRTOS
 *
 * 1 tab == 4 spaces!
 */


#ifndef PORTMACRO_H
#define PORTMACRO_H

/*-----------------------------------------------------------
 * Port specific definitions.
 *
 * The settings in this file configure FreeRTOS correctly for the
 * given hardware and compiler.
 *
 * These settings should not be altered.
 *-----------------------------------------------------------
 */
#include <avr32/io.h>
#include "intc.h"
#include "compiler.h"

#ifdef __cplusplus
extern "C" {
#endif


/* Type definitions. */
#define portCHAR        char
#define portFLOAT       float
#define portDOUBLE      double
#define portLONG        long
#define portSHORT       short
#define portSTACK_TYPE  uint32_t
#define portBASE_TYPE   long

typedef portSTACK_TYPE StackType_t;
typedef long BaseType_t;
typedef unsigned long UBaseType_t;

#define TASK_DELAY_MS(x)   ( (x)        /portTICK_PERIOD_MS )
#define TASK_DELAY_S(x)    ( (x)*1000   /portTICK_PERIOD_MS )
#define TASK_DELAY_MIN(x)  ( (x)*60*1000/portTICK_PERIOD_MS )

#define configTICK_TC_IRQ             ATPASTE2(AVR32_TC_IRQ, configTICK_TC_CHANNEL)

#if( configUSE_16_BIT_TICKS == 1 )
	typedef uint16_t TickType_t;
	#define portMAX_DELAY ( TickType_t ) 0xffff
#else
	typedef uint32_t TickType_t;
	#define portMAX_DELAY ( TickType_t ) 0xffffffffUL
#endif
/*-----------------------------------------------------------*/

/* Architecture specifics. */
#define portSTACK_GROWTH      ( -1 )
#define portTICK_PERIOD_MS      ( ( TickType_t ) 1000 / configTICK_RATE_HZ )
#define portBYTE_ALIGNMENT    4
#define portNOP()             {__asm__ __volatile__ ("nop");}
/*-----------------------------------------------------------*/


/*-----------------------------------------------------------*/

/* INTC-specific. */
#define DISABLE_ALL_EXCEPTIONS()    Disable_global_exception()
#define ENABLE_ALL_EXCEPTIONS()     Enable_global_exception()

#define DISABLE_ALL_INTERRUPTS()    Disable_global_interrupt()
#define ENABLE_ALL_INTERRUPTS()     Enable_global_interrupt()

#define DISABLE_INT_LEVEL(int_lev)  Disable_interrupt_level(int_lev)
#define ENABLE_INT_LEVEL(int_lev)   Enable_interrupt_level(int_lev)


/*
 * Debug trace.
 * Activated if and only if configDBG is nonzero.
 * Prints a formatted string to stdout.
 * The current source file name and line number are output with a colon before
 * the formatted string.
 * A carriage return and a linefeed are appended to the output.
 * stdout is redirected to the USART configured by configDBG_USART.
 * The parameters are the same as for the standard printf function.
 * There is no return value.
 * SHALL NOT BE CALLED FROM WITHIN AN INTERRUPT as fputs and printf use malloc,
 * which is interrupt-unsafe with the current __malloc_lock and __malloc_unlock.
 */
#if configDBG
#define portDBG_TRACE(...) \
{\
  fputs(__FILE__ ":" ASTRINGZ(__LINE__) ": ", stdout);\
  printf(__VA_ARGS__);\
  fputs("\r\n", stdout);\
}
#else
#define portDBG_TRACE(...)
#endif


/* Critical section management. */
#define portDISABLE_INTERRUPTS()  DISABLE_ALL_INTERRUPTS()
#define portENABLE_INTERRUPTS()   ENABLE_ALL_INTERRUPTS()


extern void vPortEnterCritical( void );
extern void vPortExitCritical( void );

#define portENTER_CRITICAL()      vPortEnterCritical();
#define portEXIT_CRITICAL()       vPortExitCritical();


/* Added as there is no such function in FreeRTOS. */
extern void *pvPortRealloc( void *pv, size_t xSize );
/*-----------------------------------------------------------*/


/*=============================================================================================*/

/*
 * Restore Context for cases other than INTi.
 */
#define portRESTORE_CONTEXT()															\
{																						\
  extern volatile uint32_t ulCriticalNesting;									\
  extern volatile void *volatile pxCurrentTCB;											\
																						\
  __asm__ __volatile__ (																\
    /* Set SP to point to new stack */													\
    "mov     r8, LO(%[pxCurrentTCB])													\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])													\n\t"\
    "ld.w    r0, r8[0]																	\n\t"\
    "ld.w    sp, r0[0]																	\n\t"\
																						\
    /* Restore ulCriticalNesting variable */											\
    "ld.w    r0, sp++																	\n\t"\
    "mov     r8, LO(%[ulCriticalNesting])												\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])												\n\t"\
    "st.w    r8[0], r0																	\n\t"\
																						\
    /* Restore R0..R7 */																\
    "ldm     sp++, r0-r7																\n\t"\
    /* R0-R7 should not be used below this line */										\
    /* Skip PC and SR (will do it at the end) */										\
    "sub     sp, -2*4																	\n\t"\
    /* Restore R8..R12 and LR */														\
    "ldm     sp++, r8-r12, lr															\n\t"\
    /* Restore SR */																	\
    "ld.w    r0, sp[-8*4]\n\t" /* R0 is modified, is restored later. */					\
    "mtsr    %[SR], r0																	\n\t"\
    /* Restore r0 */																	\
    "ld.w    r0, sp[-9*4]																\n\t"\
    /* Restore PC */																	\
    "ld.w    pc, sp[-7*4]" /* Get PC from stack - PC is the 7th register saved */		\
    :																					\
    : [ulCriticalNesting] "i" (&ulCriticalNesting),										\
      [pxCurrentTCB] "i" (&pxCurrentTCB),												\
      [SR] "i" (AVR32_SR)																\
  );																					\
}


/*
 * portSAVE_CONTEXT_INT() and portRESTORE_CONTEXT_INT(): for INT0..3 exceptions.
 * portSAVE_CONTEXT_SCALL() and portRESTORE_CONTEXT_SCALL(): for the scall exception.
 *
 * Had to make different versions because registers saved on the system stack
 * are not the same between INT0..3 exceptions and the scall exception.
 */

// Task context stack layout:
  // R8  (*)
  // R9  (*)
  // R10 (*)
  // R11 (*)
  // R12 (*)
  // R14/LR (*)
  // R15/PC (*)
  // SR (*)
  // R0
  // R1
  // R2
  // R3
  // R4
  // R5
  // R6
  // R7
  // ulCriticalNesting
// (*) automatically done for INT0..INT3, but not for SCALL

/*
 * The ISR used for the scheduler tick depends on whether the cooperative or
 * the preemptive scheduler is being used.
 */
#if configUSE_PREEMPTION == 0

/*
 * portSAVE_CONTEXT_OS_INT() for OS Tick exception.
 */
#define portSAVE_CONTEXT_OS_INT()														\
{																						\
  /* Save R0..R7 */																		\
  __asm__ __volatile__ ("stm     --sp, r0-r7");											\
																						\
  /* With the cooperative scheduler, as there is no context switch by interrupt, */		\
  /* there is also no context save. */													\
}

/*
 * portRESTORE_CONTEXT_OS_INT() for Tick exception.
 */
#define portRESTORE_CONTEXT_OS_INT()													\
{																						\
  __asm__ __volatile__ (																\
    /* Restore R0..R7 */																\
    "ldm     sp++, r0-r7\n\t"															\
																						\
    /* With the cooperative scheduler, as there is no context switch by interrupt, */	\
    /* there is also no context restore. */												\
    "rete"																				\
  );																					\
}

#else

/*
 * portSAVE_CONTEXT_OS_INT() for OS Tick exception.
 */
#define portSAVE_CONTEXT_OS_INT()																	\
{																									\
  extern volatile uint32_t ulCriticalNesting;												\
  extern volatile void *volatile pxCurrentTCB;														\
																									\
  /* When we come here */																			\
  /* Registers R8..R12, LR, PC and SR had already been pushed to system stack */					\
																									\
  __asm__ __volatile__ (																			\
    /* Save R0..R7 */																				\
    "stm     --sp, r0-r7																			\n\t"\
																									\
    /* Save ulCriticalNesting variable  - R0 is overwritten */										\
    "mov     r8, LO(%[ulCriticalNesting])\n\t"														\
    "orh     r8, HI(%[ulCriticalNesting])\n\t"														\
    "ld.w    r0, r8[0]																				\n\t"\
    "st.w    --sp, r0																				\n\t"\
																									\
    /* Check if INT0 or higher were being handled (case where the OS tick interrupted another */	\
    /* interrupt handler (which was of a higher priority level but decided to lower its priority */	\
    /* level and allow other lower interrupt level to occur). */									\
    /* In this case we don't want to do a task switch because we don't know what the stack */		\
    /* currently looks like (we don't know what the interrupted interrupt handler was doing). */	\
    /* Saving SP in pxCurrentTCB and then later restoring it (thinking restoring the task) */		\
    /* will just be restoring the interrupt handler, no way!!! */									\
    /* So, since we won't do a vTaskSwitchContext(), it's of no use to save SP. */					\
    "ld.w    r0, sp[9*4]\n\t" /* Read SR in stack */												\
    "bfextu  r0, r0, 22, 3\n\t" /* Extract the mode bits to R0. */									\
    "cp.w    r0, 1\n\t" /* Compare the mode bits with supervisor mode(b'001) */						\
    "brhi    LABEL_INT_SKIP_SAVE_CONTEXT_%[LINE]													\n\t"\
																									\
    /* Store SP in the first member of the structure pointed to by pxCurrentTCB */					\
    /* NOTE: we don't enter a critical section here because all interrupt handlers */				\
    /* MUST perform a SAVE_CONTEXT/RESTORE_CONTEXT in the same way as */							\
    /* portSAVE_CONTEXT_OS_INT/port_RESTORE_CONTEXT_OS_INT if they call OS functions. */			\
    /* => all interrupt handlers must use portENTER_SWITCHING_ISR/portEXIT_SWITCHING_ISR. */		\
    "mov     r8, LO(%[pxCurrentTCB])\n\t"															\
    "orh     r8, HI(%[pxCurrentTCB])\n\t"															\
    "ld.w    r0, r8[0]\n\t"																			\
    "st.w    r0[0], sp\n"																			\
																									\
    "LABEL_INT_SKIP_SAVE_CONTEXT_%[LINE]:"															\
    :																								\
    : [ulCriticalNesting] "i" (&ulCriticalNesting),													\
      [pxCurrentTCB] "i" (&pxCurrentTCB),															\
      [LINE] "i" (__LINE__)																			\
  );																								\
}

/*
 * portRESTORE_CONTEXT_OS_INT() for Tick exception.
 */
#define portRESTORE_CONTEXT_OS_INT()																\
{																									\
  extern volatile uint32_t ulCriticalNesting;												\
  extern volatile void *volatile pxCurrentTCB;														\
																									\
  /* Check if INT0 or higher were being handled (case where the OS tick interrupted another */		\
  /* interrupt handler (which was of a higher priority level but decided to lower its priority */	\
  /* level and allow other lower interrupt level to occur). */										\
  /* In this case we don't want to do a task switch because we don't know what the stack */			\
  /* currently looks like (we don't know what the interrupted interrupt handler was doing). */		\
  /* Saving SP in pxCurrentTCB and then later restoring it (thinking restoring the task) */			\
  /* will just be restoring the interrupt handler, no way!!! */										\
  __asm__ __volatile__ (																			\
    "ld.w    r0, sp[9*4]\n\t" /* Read SR in stack */												\
    "bfextu  r0, r0, 22, 3\n\t" /* Extract the mode bits to R0. */									\
    "cp.w    r0, 1\n\t" /* Compare the mode bits with supervisor mode(b'001) */						\
    "brhi    LABEL_INT_SKIP_RESTORE_CONTEXT_%[LINE]"												\
    :																								\
    : [LINE] "i" (__LINE__)																			\
  );																								\
																									\
  /* Else */																						\
  /* because it is here safe, always call vTaskSwitchContext() since an OS tick occurred. */		\
  /* A critical section has to be used here because vTaskSwitchContext handles FreeRTOS linked lists. */\
  portENTER_CRITICAL();																				\
  vTaskSwitchContext();																				\
  portEXIT_CRITICAL();																				\
																									\
  /* Restore all registers */																		\
																									\
  __asm__ __volatile__ (																			\
    /* Set SP to point to new stack */																\
    "mov     r8, LO(%[pxCurrentTCB])																\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])																\n\t"\
    "ld.w    r0, r8[0]																				\n\t"\
    "ld.w    sp, r0[0]																				\n"\
																									\
    "LABEL_INT_SKIP_RESTORE_CONTEXT_%[LINE]:														\n\t"\
																									\
    /* Restore ulCriticalNesting variable */														\
    "ld.w    r0, sp++																				\n\t"																			\
    "mov     r8, LO(%[ulCriticalNesting])															\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])															\n\t"\
    "st.w    r8[0], r0																				\n\t"\
																									\
    /* Restore R0..R7 */																			\
    "ldm     sp++, r0-r7																			\n\t"\
																									\
    /* Now, the stack should be R8..R12, LR, PC and SR */											\
    "rete"																							\
    :																								\
    : [ulCriticalNesting] "i" (&ulCriticalNesting),													\
      [pxCurrentTCB] "i" (&pxCurrentTCB),															\
      [LINE] "i" (__LINE__)																			\
  );																								\
}

#endif


/*
 * portSAVE_CONTEXT_SCALL() for SupervisorCALL exception.
 *
 * NOTE: taskYIELD()(== SCALL) MUST NOT be called in a mode > supervisor mode.
 *
 */
#define portSAVE_CONTEXT_SCALL()															\
{																							\
  extern volatile uint32_t ulCriticalNesting;										\
  extern volatile void *volatile pxCurrentTCB;												\
																							\
  /* Warning: the stack layout after SCALL doesn't match the one after an interrupt. */		\
  /* If SR[M2:M0] == 001 */																	\
  /*    PC and SR are on the stack.  */														\
  /* Else (other modes) */																	\
  /*    Nothing on the stack. */															\
																							\
  /* WARNING NOTE: the else case cannot happen as it is strictly forbidden to call */		\
  /* vTaskDelay() and vTaskDelayUntil() OS functions (that result in a taskYield()) */		\
  /* in an interrupt|exception handler. */													\
																							\
  __asm__ __volatile__ (																	\
    /* in order to save R0-R7 */															\
    "sub     sp, 6*4																		\n\t"\
    /* Save R0..R7 */																		\
    "stm     --sp, r0-r7																	\n\t"\
																							\
    /* in order to save R8-R12 and LR */													\
    /* do not use SP if interrupts occurs, SP must be left at bottom of stack */			\
    "sub     r7, sp,-16*4																	\n\t"\
    /* Copy PC and SR in other places in the stack. */										\
    "ld.w    r0, r7[-2*4]																	\n\t" /* Read SR */\
    "st.w    r7[-8*4], r0																	\n\t" /* Copy SR */\
    "ld.w    r0, r7[-1*4]																	\n\t" /* Read PC */\
    "st.w    r7[-7*4], r0																	\n\t" /* Copy PC */\
																							\
    /* Save R8..R12 and LR on the stack. */													\
    "stm     --r7, r8-r12, lr																\n\t"\
																							\
    /* Arriving here we have the following stack organizations: */							\
    /* R8..R12, LR, PC, SR, R0..R7. */														\
																							\
    /* Now we can finalize the save. */														\
																							\
    /* Save ulCriticalNesting variable  - R0 is overwritten */								\
    "mov     r8, LO(%[ulCriticalNesting])													\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])													\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "st.w    --sp, r0"																		\
    :																						\
    : [ulCriticalNesting] "i" (&ulCriticalNesting)											\
  );																						\
																							\
  /* Disable the its which may cause a context switch (i.e. cause a change of */			\
  /* pxCurrentTCB). */																		\
  /* Basically, all accesses to the pxCurrentTCB structure should be put in a */			\
  /* critical section because it is a global structure. */									\
  portENTER_CRITICAL();																		\
																							\
  /* Store SP in the first member of the structure pointed to by pxCurrentTCB */			\
  __asm__ __volatile__ (																	\
    "mov     r8, LO(%[pxCurrentTCB])														\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])														\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "st.w    r0[0], sp"																		\
    :																						\
    : [pxCurrentTCB] "i" (&pxCurrentTCB)													\
  );																						\
}

/*
 * portRESTORE_CONTEXT() for SupervisorCALL exception.
 */
#define portRESTORE_CONTEXT_SCALL()															\
{																							\
  extern volatile uint32_t ulCriticalNesting;										\
  extern volatile void *volatile pxCurrentTCB;												\
																							\
  /* Restore all registers */																\
																							\
  /* Set SP to point to new stack */														\
  __asm__ __volatile__ (																	\
    "mov     r8, LO(%[pxCurrentTCB])														\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])														\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "ld.w    sp, r0[0]"																		\
    :																						\
    : [pxCurrentTCB] "i" (&pxCurrentTCB)													\
  );																						\
																							\
  /* Leave pxCurrentTCB variable access critical section */									\
  portEXIT_CRITICAL();																		\
																							\
  __asm__ __volatile__ (																	\
    /* Restore ulCriticalNesting variable */												\
    "ld.w    r0, sp++																		\n\t"\
    "mov     r8, LO(%[ulCriticalNesting])													\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])													\n\t"\
    "st.w    r8[0], r0																		\n\t"\
																							\
    /* skip PC and SR */																	\
    /* do not use SP if interrupts occurs, SP must be left at bottom of stack */			\
    "sub     r7, sp, -10*4																	\n\t"\
    /* Restore r8-r12 and LR */																\
    "ldm     r7++, r8-r12, lr																\n\t"\
																							\
    /* RETS will take care of the extra PC and SR restore. */								\
    /* So, we have to prepare the stack for this. */										\
    "ld.w    r0, r7[-8*4]																	\n\t" /* Read SR */\
    "st.w    r7[-2*4], r0																	\n\t" /* Copy SR */\
    "ld.w    r0, r7[-7*4]																	\n\t" /* Read PC */\
    "st.w    r7[-1*4], r0																	\n\t" /* Copy PC */\
																							\
    /* Restore R0..R7 */																	\
    "ldm     sp++, r0-r7																	\n\t"\
																							\
    "sub     sp, -6*4																		\n\t"\
																							\
    "rets"																					\
    :																						\
    : [ulCriticalNesting] "i" (&ulCriticalNesting)											\
  );																						\
}


/*
 * The ISR used depends on whether the cooperative or
 * the preemptive scheduler is being used.
 */
#if configUSE_PREEMPTION == 0

/*
 * ISR entry and exit macros.  These are only required if a task switch
 * is required from the ISR.
 */
#define portENTER_SWITCHING_ISR()															\
{																							\
  /* Save R0..R7 */																			\
  __asm__ __volatile__ ("stm     --sp, r0-r7");												\
																							\
  /* With the cooperative scheduler, as there is no context switch by interrupt, */			\
  /* there is also no context save. */														\
}

/*
 * Input parameter: in R12, boolean. Perform a vTaskSwitchContext() if 1
 */
#define portEXIT_SWITCHING_ISR()															\
{																							\
  __asm__ __volatile__ (																	\
    /* Restore R0..R7 */																	\
    "ldm     sp++, r0-r7																	\n\t"\
																							\
    /* With the cooperative scheduler, as there is no context switch by interrupt, */		\
    /* there is also no context restore. */													\
    "rete"																					\
  );																						\
}

#else

/*
 * ISR entry and exit macros.  These are only required if a task switch
 * is required from the ISR.
 */
#define portENTER_SWITCHING_ISR()															\
{																							\
  extern volatile uint32_t ulCriticalNesting;										\
  extern volatile void *volatile pxCurrentTCB;												\
																							\
  /* When we come here */																	\
  /* Registers R8..R12, LR, PC and SR had already been pushed to system stack */			\
																							\
  __asm__ __volatile__ (																	\
    /* Save R0..R7 */																		\
    "stm     --sp, r0-r7																	\n\t"\
																							\
    /* Save ulCriticalNesting variable  - R0 is overwritten */								\
    "mov     r8, LO(%[ulCriticalNesting])													\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])													\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "st.w    --sp, r0																		\n\t"\
																									\
    /* Check if INT0 or higher were being handled (case where the OS tick interrupted another */	\
    /* interrupt handler (which was of a higher priority level but decided to lower its priority */	\
    /* level and allow other lower interrupt level to occur). */									\
    /* In this case we don't want to do a task switch because we don't know what the stack */		\
    /* currently looks like (we don't know what the interrupted interrupt handler was doing). */	\
    /* Saving SP in pxCurrentTCB and then later restoring it (thinking restoring the task) */		\
    /* will just be restoring the interrupt handler, no way!!! */									\
    /* So, since we won't do a vTaskSwitchContext(), it's of no use to save SP. */					\
    "ld.w    r0, sp[9*4]																	\n\t" /* Read SR in stack */\
    "bfextu  r0, r0, 22, 3																	\n\t" /* Extract the mode bits to R0. */\
    "cp.w    r0, 1																			\n\t" /* Compare the mode bits with supervisor mode(b'001) */\
    "brhi    LABEL_ISR_SKIP_SAVE_CONTEXT_%[LINE]											\n\t"\
																							\
    /* Store SP in the first member of the structure pointed to by pxCurrentTCB */			\
    "mov     r8, LO(%[pxCurrentTCB])														\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])														\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "st.w    r0[0], sp																		\n"\
																							\
    "LABEL_ISR_SKIP_SAVE_CONTEXT_%[LINE]:"													\
    :																						\
    : [ulCriticalNesting] "i" (&ulCriticalNesting),											\
      [pxCurrentTCB] "i" (&pxCurrentTCB),													\
      [LINE] "i" (__LINE__)																	\
  );																						\
}

/*
 * Input parameter: in R12, boolean. Perform a vTaskSwitchContext() if 1
 */
#define portEXIT_SWITCHING_ISR()															\
{																							\
  extern volatile uint32_t ulCriticalNesting;										\
  extern volatile void *volatile pxCurrentTCB;												\
																							\
  __asm__ __volatile__ (																	\
    /* Check if INT0 or higher were being handled (case where the OS tick interrupted another */		\
    /* interrupt handler (which was of a higher priority level but decided to lower its priority */		\
    /* level and allow other lower interrupt level to occur). */										\
    /* In this case it's of no use to switch context and restore a new SP because we purposedly */		\
    /* did not previously save SP in its TCB. */																				\
    "ld.w    r0, sp[9*4]																	\n\t" /* Read SR in stack */\
    "bfextu  r0, r0, 22, 3																	\n\t" /* Extract the mode bits to R0. */\
    "cp.w    r0, 1																			\n\t" /* Compare the mode bits with supervisor mode(b'001) */\
    "brhi    LABEL_ISR_SKIP_RESTORE_CONTEXT_%[LINE]											\n\t"\
																							\
    /* If a switch is required then we just need to call */									\
    /* vTaskSwitchContext() as the context has already been */								\
    /* saved. */																			\
    "cp.w    r12, 1																			\n\t" /* Check if Switch context is required. */\
    "brne    LABEL_ISR_RESTORE_CONTEXT_%[LINE]"												\
    :																						\
    : [LINE] "i" (__LINE__)																	\
  );																						\
																							\
  /* A critical section has to be used here because vTaskSwitchContext handles FreeRTOS linked lists. */	\
  portENTER_CRITICAL();																		\
  vTaskSwitchContext();																		\
  portEXIT_CRITICAL();																		\
																							\
  __asm__ __volatile__ (																	\
    "LABEL_ISR_RESTORE_CONTEXT_%[LINE]:														\n\t"\
    /* Restore the context of which ever task is now the highest */							\
    /* priority that is ready to run. */													\
																							\
    /* Restore all registers */																\
																							\
    /* Set SP to point to new stack */														\
    "mov     r8, LO(%[pxCurrentTCB])														\n\t"\
    "orh     r8, HI(%[pxCurrentTCB])														\n\t"\
    "ld.w    r0, r8[0]																		\n\t"\
    "ld.w    sp, r0[0]																		\n"\
																							\
    "LABEL_ISR_SKIP_RESTORE_CONTEXT_%[LINE]:												\n\t"\
																							\
    /* Restore ulCriticalNesting variable */												\
    "ld.w    r0, sp++																		\n\t"\
    "mov     r8, LO(%[ulCriticalNesting])													\n\t"\
    "orh     r8, HI(%[ulCriticalNesting])													\n\t"\
    "st.w    r8[0], r0																		\n\t"\
																							\
    /* Restore R0..R7 */																	\
    "ldm     sp++, r0-r7																	\n\t"\
																							\
    /* Now, the stack should be R8..R12, LR, PC and SR  */									\
    "rete"																					\
    :																						\
    : [ulCriticalNesting] "i" (&ulCriticalNesting),											\
      [pxCurrentTCB] "i" (&pxCurrentTCB),													\
      [LINE] "i" (__LINE__)																	\
  );																						\
}

#endif


#define portYIELD()                 {__asm__ __volatile__ ("scall");}

/* Task function macros as described on the FreeRTOS.org WEB site. */
#define portTASK_FUNCTION_PROTO( vFunction, pvParameters ) void vFunction( void *pvParameters )
#define portTASK_FUNCTION( vFunction, pvParameters ) void vFunction( void *pvParameters )

#ifdef __cplusplus
}
#endif

#endif /* PORTMACRO_H */