FreeRTOS/Demo/CORTEX_MPU_Simulator_Keil_GCC/Keil_Specific/RegTest.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /*
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     the terms of the GNU General Public License (version 2) as published by the
     Free Software Foundation >>>> AND MODIFIED BY <<<< the FreeRTOS exception.

     ***************************************************************************
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     >>!   outside of the FreeRTOS kernel.                                   !<<
     ***************************************************************************

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     ***************************************************************************
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 */

 /* FreeRTOS includes. */
 #include "FreeRTOS.h"
 #include "queue.h"
 #include "task.h"

 /*
  * "Reg test" tasks - These fill the registers with known values, then check
  * that each register maintains its expected value for the lifetime of the
  * task.  Each task uses a different set of values.  The reg test tasks execute
  * with a very low priority, so get preempted very frequently.  A register
  * containing an unexpected value is indicative of an error in the context
  * switching mechanism.
  */

 void vRegTest1Implementation( void *pvParameters );
 void vRegTest2Implementation( void *pvParameters );
 void vRegTest3Implementation( void );
 void vRegTest4Implementation( void );

 /*
  * Used as an easy way of deleting a task from inline assembly.
  */
 extern void vMainDeleteMe( void ) __attribute__((noinline));

 /*
  * Used by the first two reg test tasks and a software timer callback function
  * to send messages to the check task.  The message just lets the check task
  * know that the tasks and timer are still functioning correctly.  If a reg test
  * task detects an error it will delete itself, and in so doing prevent itself
  * from sending any more 'I'm Alive' messages to the check task.
  */
 extern void vMainSendImAlive( QueueHandle_t xHandle, uint32_t ulTaskNumber );

 /* The queue used to send a message to the check task. */
 extern QueueHandle_t xGlobalScopeCheckQueue;

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

 void vRegTest1Implementation( void *pvParameters )
 {
 /* This task is created in privileged mode so can access the file scope
 queue variable.  Take a stack copy of this before the task is set into user
 mode.  Once this task is in user mode the file scope queue variable will no
 longer be accessible but the stack copy will. */
 QueueHandle_t xQueue = xGlobalScopeCheckQueue;
 const TickType_t xDelayTime = pdMS_TO_TICKS( 100UL );

 	/* Now the queue handle has been obtained the task can switch to user
 	mode.  This is just one method of passing a handle into a protected
 	task, the other	reg test task uses the task parameter instead. */
 	portSWITCH_TO_USER_MODE();

 	/* First check that the parameter value is as expected. */
 	if( pvParameters != ( void * ) configREG_TEST_TASK_1_PARAMETER )
 	{
 		/* Error detected.  Delete the task so it stops communicating with
 		the check task. */
 		vMainDeleteMe();
 	}

 	for( ;; )
 	{
 		#if defined ( __GNUC__ )
 		{
 			/* This task tests the kernel context switch mechanism by reading and
 			writing directly to registers - which requires the test to be written
 			in assembly code. */
 			__asm volatile
 			(
 				"		MOV	R4, #104			\n" /* Set registers to a known value.  R0 to R1 are done in the loop below. */
 				"		MOV	R5, #105			\n"
 				"		MOV	R6, #106			\n"
 				"		MOV	R8, #108			\n"
 				"		MOV	R9, #109			\n"
 				"		MOV	R10, #110			\n"
 				"		MOV	R11, #111			\n"
 				"reg1loop:						\n"
 				"		MOV	R0, #100			\n" /* Set the scratch registers to known values - done inside the loop as they get clobbered. */
 				"		MOV	R1, #101			\n"
 				"		MOV	R2, #102			\n"
 				"		MOV R3, #103			\n"
 				"		MOV	R12, #112			\n"
 				"		SVC #1					\n" /* Yield just to increase test coverage. */
 				"		CMP	R0, #100			\n" /* Check all the registers still contain their expected values. */
 				"		BNE	vMainDeleteMe		\n" /* Value was not as expected, delete the task so it stops communicating with the check task. */
 				"		CMP	R1, #101			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R2, #102			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP R3, #103			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R4, #104			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R5, #105			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R6, #106			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R8, #108			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R9, #109			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R10, #110			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R11, #111			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R12, #112			\n"
 				"		BNE	vMainDeleteMe		\n"
 				:::"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r8", "r9", "r10", "r11", "r12"
 			);
 		}
 		#endif /* __GNUC__ */

 		/* Send configREG_TEST_1_STILL_EXECUTING to the check task to indicate that this
 		task is still functioning. */
 		vMainSendImAlive( xQueue, configREG_TEST_1_STILL_EXECUTING );
 		vTaskDelay( xDelayTime );

 		#if defined ( __GNUC__ )
 		{
 			/* Go back to check all the register values again. */
 			__asm volatile( "		B reg1loop	" );
 		}
 		#endif /* __GNUC__ */
 	}
 }
 /*-----------------------------------------------------------*/

 void vRegTest2Implementation( void *pvParameters )
 {
 /* The queue handle is passed in as the task parameter.  This is one method of
 passing data into a protected task, the other reg test task uses a different
 method. */
 QueueHandle_t xQueue = ( QueueHandle_t ) pvParameters;
 const TickType_t xDelayTime = pdMS_TO_TICKS( 100UL );

 	for( ;; )
 	{
 		#if defined ( __GNUC__ )
 		{
 			/* This task tests the kernel context switch mechanism by reading and
 			writing directly to registers - which requires the test to be written
 			in assembly code. */
 			__asm volatile
 			(
 				"		MOV	R4, #4				\n" /* Set registers to a known value.  R0 to R1 are done in the loop below. */
 				"		MOV	R5, #5				\n"
 				"		MOV	R6, #6				\n"
 				"		MOV	R8, #8				\n" /* Frame pointer is omitted as it must not be changed. */
 				"		MOV	R9, #9				\n"
 				"		MOV	R10, 10				\n"
 				"		MOV	R11, #11			\n"
 				"reg2loop:						\n"
 				"		MOV	R0, #13				\n" /* Set the scratch registers to known values - done inside the loop as they get clobbered. */
 				"		MOV	R1, #1				\n"
 				"		MOV	R2, #2				\n"
 				"		MOV R3, #3				\n"
 				"		MOV	R12, #12			\n"
 				"		CMP	R0, #13				\n" /* Check all the registers still contain their expected values. */
 				"		BNE	vMainDeleteMe		\n" /* Value was not as expected, delete the task so it stops communicating with the check task */
 				"		CMP	R1, #1				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R2, #2				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP R3, #3				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R4, #4				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R5, #5				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R6, #6				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R8, #8				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R9, #9				\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R10, #10			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R11, #11			\n"
 				"		BNE	vMainDeleteMe		\n"
 				"		CMP	R12, #12			\n"
 				"		BNE	vMainDeleteMe		\n"
 				:::"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r8", "r9", "r10", "r11", "r12"
 			);
 		}
 		#endif /* __GNUC__ */

 		/* Send configREG_TEST_2_STILL_EXECUTING to the check task to indicate
 		that this task is still functioning. */
 		vMainSendImAlive( xQueue, configREG_TEST_2_STILL_EXECUTING );
 		vTaskDelay( xDelayTime );

 		#if defined ( __GNUC__ )
 		{
 			/* Go back to check all the register values again. */
 			__asm volatile( "		B reg2loop	" );
 		}
 		#endif /* __GNUC__ */
 	}
 }
 /*-----------------------------------------------------------*/

 __asm void vRegTest3Implementation( void )
 {
 	extern pulRegTest3LoopCounter

 	PRESERVE8

 	/* Fill the core registers with known values. */
 	mov	r0, #100
 	mov	r1, #101
 	mov	r2, #102
 	mov	r3, #103
 	mov	r4, #104
 	mov	r5, #105
 	mov	r6, #106
 	mov	r7, #107
 	mov	r8, #108
 	mov	r9, #109
 	mov	r10, #110
 	mov	r11, #111
 	mov	r12, #112

 	/* Fill the VFP registers with known values. */
 	vmov	d0, r0, r1
 	vmov	d1, r2, r3
 	vmov	d2, r4, r5
 	vmov	d3, r6, r7
 	vmov	d4, r8, r9
 	vmov	d5, r10, r11
 	vmov	d6, r0, r1
 	vmov	d7, r2, r3
 	vmov	d8, r4, r5
 	vmov	d9, r6, r7
 	vmov	d10, r8, r9
 	vmov	d11, r10, r11
 	vmov	d12, r0, r1
 	vmov	d13, r2, r3
 	vmov	d14, r4, r5
 	vmov	d15, r6, r7

 reg1_loop

 	/* Check all the VFP registers still contain the values set above.
 	First save registers that are clobbered by the test. */
 	push { r0-r1 }

 	vmov	r0, r1, d0
 	cmp 	r0, #100
 	bne 	reg1_error_loopf
 	cmp 	r1, #101
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d1
 	cmp 	r0, #102
 	bne 	reg1_error_loopf
 	cmp 	r1, #103
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d2
 	cmp 	r0, #104
 	bne 	reg1_error_loopf
 	cmp 	r1, #105
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d3
 	cmp 	r0, #106
 	bne 	reg1_error_loopf
 	cmp 	r1, #107
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d4
 	cmp 	r0, #108
 	bne 	reg1_error_loopf
 	cmp 	r1, #109
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d5
 	cmp 	r0, #110
 	bne 	reg1_error_loopf
 	cmp 	r1, #111
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d6
 	cmp 	r0, #100
 	bne 	reg1_error_loopf
 	cmp 	r1, #101
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d7
 	cmp 	r0, #102
 	bne 	reg1_error_loopf
 	cmp 	r1, #103
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d8
 	cmp 	r0, #104
 	bne 	reg1_error_loopf
 	cmp 	r1, #105
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d9
 	cmp 	r0, #106
 	bne 	reg1_error_loopf
 	cmp 	r1, #107
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d10
 	cmp 	r0, #108
 	bne 	reg1_error_loopf
 	cmp 	r1, #109
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d11
 	cmp 	r0, #110
 	bne 	reg1_error_loopf
 	cmp 	r1, #111
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d12
 	cmp 	r0, #100
 	bne 	reg1_error_loopf
 	cmp 	r1, #101
 	bne 	reg1_error_loopf
 	vmov	r0, r1, d13
 	cmp 	r0, #102
 	bne 	reg1_error_loopf
 	cmp 	r1, #103
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d14
 	cmp 	r0, #104
 	bne 	reg1_error_loopf
 	cmp 	r1, #105
 	bne 	reg1_error_loopf
 	vmov 	r0, r1, d15
 	cmp 	r0, #106
 	bne 	reg1_error_loopf
 	cmp 	r1, #107
 	bne 	reg1_error_loopf

 	/* Restore the registers that were clobbered by the test. */
 	pop 	{r0-r1}

 	/* VFP register test passed.  Jump to the core register test. */
 	b 		reg1_loopf_pass

 reg1_error_loopf
 	/* If this line is hit then a VFP register value was found to be incorrect. */
 	b reg1_error_loopf

 reg1_loopf_pass

 	cmp	r0, #100
 	bne	reg1_error_loop
 	cmp	r1, #101
 	bne	reg1_error_loop
 	cmp	r2, #102
 	bne	reg1_error_loop
 	cmp 	r3, #103
 	bne	reg1_error_loop
 	cmp	r4, #104
 	bne	reg1_error_loop
 	cmp	r5, #105
 	bne	reg1_error_loop
 	cmp	r6, #106
 	bne	reg1_error_loop
 	cmp	r7, #107
 	bne	reg1_error_loop
 	cmp	r8, #108
 	bne	reg1_error_loop
 	cmp	r9, #109
 	bne	reg1_error_loop
 	cmp	r10, #110
 	bne	reg1_error_loop
 	cmp	r11, #111
 	bne	reg1_error_loop
 	cmp	r12, #112
 	bne	reg1_error_loop

 	/* Everything passed, increment the loop counter. */
 	push 	{ r0-r1 }
 	ldr	r0, =pulRegTest3LoopCounter
 	ldr	r0, [r0]
 	ldr 	r1, [r0]
 	adds 	r1, r1, #1
 	str 	r1, [r0]
 	pop 	{ r0-r1 }

 	/* Start again. */
 	b 		reg1_loop

 reg1_error_loop
 	/* If this line is hit then there was an error in a core register value.
 	The loop ensures the loop counter stops incrementing. */
 	b 	reg1_error_loop
 	nop
 	nop
 }
 /*-----------------------------------------------------------*/

 __asm void vRegTest4Implementation( void )
 {
 	extern pulRegTest4LoopCounter;

 	PRESERVE8

 	/* Set all the core registers to known values. */
 	mov 	r0, #-1
 	mov 	r1, #1
 	mov 	r2, #2
 	mov 	r3, #3
 	mov	r4, #4
 	mov	r5, #5
 	mov	r6, #6
 	mov 	r7, #7
 	mov	r8, #8
 	mov	r9, #9
 	mov	r10, #10
 	mov	r11, #11
 	mov 	r12, #12

 	/* Set all the VFP to known values. */
 	vmov 	d0, r0, r1
 	vmov 	d1, r2, r3
 	vmov 	d2, r4, r5
 	vmov 	d3, r6, r7
 	vmov 	d4, r8, r9
 	vmov 	d5, r10, r11
 	vmov 	d6, r0, r1
 	vmov 	d7, r2, r3
 	vmov 	d8, r4, r5
 	vmov 	d9, r6, r7
 	vmov 	d10, r8, r9
 	vmov 	d11, r10, r11
 	vmov 	d12, r0, r1
 	vmov 	d13, r2, r3
 	vmov 	d14, r4, r5
 	vmov 	d15, r6, r7

 reg2_loop

 	/* Check all the VFP registers still contain the values set above.
 	First save registers that are clobbered by the test. */
 	push { r0-r1 }

 	vmov	r0, r1, d0
 	cmp	r0, #-1
 	bne	reg2_error_loopf
 	cmp	r1, #1
 	bne	reg2_error_loopf
 	vmov	r0, r1, d1
 	cmp 	r0, #2
 	bne 	reg2_error_loopf
 	cmp 	r1, #3
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d2
 	cmp 	r0, #4
 	bne 	reg2_error_loopf
 	cmp 	r1, #5
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d3
 	cmp 	r0, #6
 	bne 	reg2_error_loopf
 	cmp 	r1, #7
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d4
 	cmp 	r0, #8
 	bne 	reg2_error_loopf
 	cmp 	r1, #9
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d5
 	cmp 	r0, #10
 	bne 	reg2_error_loopf
 	cmp 	r1, #11
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d6
 	cmp 	r0, #-1
 	bne 	reg2_error_loopf
 	cmp 	r1, #1
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d7
 	cmp 	r0, #2
 	bne 	reg2_error_loopf
 	cmp 	r1, #3
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d8
 	cmp 	r0, #4
 	bne 	reg2_error_loopf
 	cmp 	r1, #5
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d9
 	cmp 	r0, #6
 	bne 	reg2_error_loopf
 	cmp 	r1, #7
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d10
 	cmp 	r0, #8
 	bne 	reg2_error_loopf
 	cmp 	r1, #9
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d11
 	cmp 	r0, #10
 	bne 	reg2_error_loopf
 	cmp 	r1, #11
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d12
 	cmp 	r0, #-1
 	bne 	reg2_error_loopf
 	cmp 	r1, #1
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d13
 	cmp 	r0, #2
 	bne 	reg2_error_loopf
 	cmp 	r1, #3
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d14
 	cmp 	r0, #4
 	bne 	reg2_error_loopf
 	cmp 	r1, #5
 	bne 	reg2_error_loopf
 	vmov 	r0, r1, d15
 	cmp 	r0, #6
 	bne 	reg2_error_loopf
 	cmp 	r1, #7
 	bne 	reg2_error_loopf

 	/* Restore the registers that were clobbered by the test. */
 	pop 	{r0-r1}

 	/* VFP register test passed.  Jump to the core register test. */
 	b 		reg2_loopf_pass

 reg2_error_loopf
 	/* If this line is hit then a VFP register value was found to be
 	incorrect. */
 	b reg2_error_loopf

 reg2_loopf_pass

 	cmp	r0, #-1
 	bne	reg2_error_loop
 	cmp	r1, #1
 	bne	reg2_error_loop
 	cmp	r2, #2
 	bne	reg2_error_loop
 	cmp 	r3, #3
 	bne	reg2_error_loop
 	cmp	r4, #4
 	bne	reg2_error_loop
 	cmp	r5, #5
 	bne	reg2_error_loop
 	cmp	r6, #6
 	bne	reg2_error_loop
 	cmp	r7, #7
 	bne	reg2_error_loop
 	cmp	r8, #8
 	bne	reg2_error_loop
 	cmp	r9, #9
 	bne	reg2_error_loop
 	cmp	r10, #10
 	bne	reg2_error_loop
 	cmp	r11, #11
 	bne	reg2_error_loop
 	cmp	r12, #12
 	bne	reg2_error_loop

 	/* Increment the loop counter so the check task knows this task is
 	still running. */
 	push	{ r0-r1 }
 	ldr	r0, =pulRegTest4LoopCounter
 	ldr	r0, [r0]
 	ldr 	r1, [r0]
 	adds 	r1, r1, #1
 	str 	r1, [r0]
 	pop { r0-r1 }

 	/* Yield to increase test coverage. */
 	SVC #1

 	/* Start again. */
 	b reg2_loop

 reg2_error_loop
 	/* If this line is hit then there was an error in a core register value.
 	This loop ensures the loop counter variable stops incrementing. */
 	b reg2_error_loop
 	nop
 }
 /*-----------------------------------------------------------*/

 /* Fault handlers are here for convenience as they use compiler specific syntax
 and this file is specific to the Keil compiler. */
 void hard_fault_handler( uint32_t * hardfault_args )
 {
 volatile uint32_t stacked_r0;
 volatile uint32_t stacked_r1;
 volatile uint32_t stacked_r2;
 volatile uint32_t stacked_r3;
 volatile uint32_t stacked_r12;
 volatile uint32_t stacked_lr;
 volatile uint32_t stacked_pc;
 volatile uint32_t stacked_psr;

 	stacked_r0 = ((uint32_t) hardfault_args[ 0 ]);
 	stacked_r1 = ((uint32_t) hardfault_args[ 1 ]);
 	stacked_r2 = ((uint32_t) hardfault_args[ 2 ]);
 	stacked_r3 = ((uint32_t) hardfault_args[ 3 ]);

 	stacked_r12 = ((uint32_t) hardfault_args[ 4 ]);
 	stacked_lr = ((uint32_t) hardfault_args[ 5 ]);
 	stacked_pc = ((uint32_t) hardfault_args[ 6 ]);
 	stacked_psr = ((uint32_t) hardfault_args[ 7 ]);

 	/* Inspect stacked_pc to locate the offending instruction. */
 	for( ;; );
 }
 /*-----------------------------------------------------------*/

 void HardFault_Handler( void );
 __asm void HardFault_Handler( void )
 {
 	extern hard_fault_handler

 	tst lr, #4
 	ite eq
 	mrseq r0, msp
 	mrsne r0, psp
 	ldr r1, [r0, #24]
 	ldr r2, hard_fault_handler
 	bx r2
 }
 /*-----------------------------------------------------------*/

 void MemManage_Handler( void );
 __asm void MemManage_Handler( void )
 {
 	extern hard_fault_handler

 	tst lr, #4
 	ite eq
 	mrseq r0, msp
 	mrsne r0, psp
 	ldr r1, [r0, #24]
 	ldr r2, hard_fault_handler
 	bx r2
 }
 /*-----------------------------------------------------------*/
	/*
	FreeRTOS V9.0.0 - Copyright (C) 2015 Real Time Engineers Ltd.
	All rights reserved

	VISIT http://www.FreeRTOS.org TO ENSURE YOU ARE USING THE LATEST VERSION.

	This file is part of the FreeRTOS distribution.

	FreeRTOS is free software; you can redistribute it and/or modify it under
	the terms of the GNU General Public License (version 2) as published by the
	Free Software Foundation >>>> AND MODIFIED BY <<<< the FreeRTOS exception.

	***************************************************************************
	>>! NOTE: The modification to the GPL is included to allow you to !<<
	>>! distribute a combined work that includes FreeRTOS without being !<<
	>>! obliged to provide the source code for proprietary components !<<
	>>! outside of the FreeRTOS kernel. !<<
	***************************************************************************

	FreeRTOS 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. Full license text is available on the following
	link: http://www.freertos.org/a00114.html

	***************************************************************************
	* *
	* FreeRTOS provides completely free yet professionally developed, *
	* robust, strictly quality controlled, supported, and cross *
	* platform software that is more than just the market leader, it *
	* is the industry's de facto standard. *
	* *
	* Help yourself get started quickly while simultaneously helping *
	* to support the FreeRTOS project by purchasing a FreeRTOS *
	* tutorial book, reference manual, or both: *
	* http://www.FreeRTOS.org/Documentation *
	* *
	***************************************************************************

	http://www.FreeRTOS.org/FAQHelp.html - Having a problem? Start by reading
	the FAQ page "My application does not run, what could be wrong?". Have you
	defined configASSERT()?

	http://www.FreeRTOS.org/support - In return for receiving this top quality
	embedded software for free we request you assist our global community by
	participating in the support forum.

	http://www.FreeRTOS.org/training - Investing in training allows your team to
	be as productive as possible as early as possible. Now you can receive
	FreeRTOS training directly from Richard Barry, CEO of Real Time Engineers
	Ltd, and the world's leading authority on the world's leading RTOS.

	http://www.FreeRTOS.org/plus - A selection of FreeRTOS ecosystem products,
	including FreeRTOS+Trace - an indispensable productivity tool, a DOS
	compatible FAT file system, and our tiny thread aware UDP/IP stack.

	http://www.FreeRTOS.org/labs - Where new FreeRTOS products go to incubate.
	Come and try FreeRTOS+TCP, our new open source TCP/IP stack for FreeRTOS.

	http://www.OpenRTOS.com - Real Time Engineers ltd. license FreeRTOS to High
	Integrity Systems ltd. to sell under the OpenRTOS brand. Low cost OpenRTOS
	licenses offer ticketed support, indemnification and commercial middleware.

	http://www.SafeRTOS.com - High Integrity Systems also provide a safety
	engineered and independently SIL3 certified version for use in safety and
	mission critical applications that require provable dependability.

	1 tab == 4 spaces!
	*/

	/* FreeRTOS includes. */
	#include "FreeRTOS.h"
	#include "queue.h"
	#include "task.h"

	/*
	* "Reg test" tasks - These fill the registers with known values, then check
	* that each register maintains its expected value for the lifetime of the
	* task. Each task uses a different set of values. The reg test tasks execute
	* with a very low priority, so get preempted very frequently. A register
	* containing an unexpected value is indicative of an error in the context
	* switching mechanism.
	*/

	void vRegTest1Implementation( void *pvParameters );
	void vRegTest2Implementation( void *pvParameters );
	void vRegTest3Implementation( void );
	void vRegTest4Implementation( void );

	/*
	* Used as an easy way of deleting a task from inline assembly.
	*/
	extern void vMainDeleteMe( void ) __attribute__((noinline));

	/*
	* Used by the first two reg test tasks and a software timer callback function
	* to send messages to the check task. The message just lets the check task
	* know that the tasks and timer are still functioning correctly. If a reg test
	* task detects an error it will delete itself, and in so doing prevent itself
	* from sending any more 'I'm Alive' messages to the check task.
	*/
	extern void vMainSendImAlive( QueueHandle_t xHandle, uint32_t ulTaskNumber );

	/* The queue used to send a message to the check task. */
	extern QueueHandle_t xGlobalScopeCheckQueue;

	/-----------------------------------------------------------/

	void vRegTest1Implementation( void *pvParameters )
	{
	/* This task is created in privileged mode so can access the file scope
	queue variable. Take a stack copy of this before the task is set into user
	mode. Once this task is in user mode the file scope queue variable will no
	longer be accessible but the stack copy will. */
	QueueHandle_t xQueue = xGlobalScopeCheckQueue;
	const TickType_t xDelayTime = pdMS_TO_TICKS( 100UL );

	/* Now the queue handle has been obtained the task can switch to user
	mode. This is just one method of passing a handle into a protected
	task, the other reg test task uses the task parameter instead. */
	portSWITCH_TO_USER_MODE();

	/* First check that the parameter value is as expected. */
	if( pvParameters != ( void * ) configREG_TEST_TASK_1_PARAMETER )
	{
	/* Error detected. Delete the task so it stops communicating with
	the check task. */
	vMainDeleteMe();
	}

	for( ;; )
	{
	#if defined ( __GNUC__ )
	{
	/* This task tests the kernel context switch mechanism by reading and
	writing directly to registers - which requires the test to be written
	in assembly code. */
	__asm volatile
	(
	" MOV R4, #104 \n" /* Set registers to a known value. R0 to R1 are done in the loop below. */
	" MOV R5, #105 \n"
	" MOV R6, #106 \n"
	" MOV R8, #108 \n"
	" MOV R9, #109 \n"
	" MOV R10, #110 \n"
	" MOV R11, #111 \n"
	"reg1loop: \n"
	" MOV R0, #100 \n" /* Set the scratch registers to known values - done inside the loop as they get clobbered. */
	" MOV R1, #101 \n"
	" MOV R2, #102 \n"
	" MOV R3, #103 \n"
	" MOV R12, #112 \n"
	" SVC #1 \n" /* Yield just to increase test coverage. */
	" CMP R0, #100 \n" /* Check all the registers still contain their expected values. */
	" BNE vMainDeleteMe \n" /* Value was not as expected, delete the task so it stops communicating with the check task. */
	" CMP R1, #101 \n"
	" BNE vMainDeleteMe \n"
	" CMP R2, #102 \n"
	" BNE vMainDeleteMe \n"
	" CMP R3, #103 \n"
	" BNE vMainDeleteMe \n"
	" CMP R4, #104 \n"
	" BNE vMainDeleteMe \n"
	" CMP R5, #105 \n"
	" BNE vMainDeleteMe \n"
	" CMP R6, #106 \n"
	" BNE vMainDeleteMe \n"
	" CMP R8, #108 \n"
	" BNE vMainDeleteMe \n"
	" CMP R9, #109 \n"
	" BNE vMainDeleteMe \n"
	" CMP R10, #110 \n"
	" BNE vMainDeleteMe \n"
	" CMP R11, #111 \n"
	" BNE vMainDeleteMe \n"
	" CMP R12, #112 \n"
	" BNE vMainDeleteMe \n"
	:::"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r8", "r9", "r10", "r11", "r12"
	);
	}
	#endif /* __GNUC__ */

	/* Send configREG_TEST_1_STILL_EXECUTING to the check task to indicate that this
	task is still functioning. */
	vMainSendImAlive( xQueue, configREG_TEST_1_STILL_EXECUTING );
	vTaskDelay( xDelayTime );

	#if defined ( __GNUC__ )
	{
	/* Go back to check all the register values again. */
	__asm volatile( " B reg1loop " );
	}
	#endif /* __GNUC__ */
	}
	}
	/-----------------------------------------------------------/

	void vRegTest2Implementation( void *pvParameters )
	{
	/* The queue handle is passed in as the task parameter. This is one method of
	passing data into a protected task, the other reg test task uses a different
	method. */
	QueueHandle_t xQueue = ( QueueHandle_t ) pvParameters;
	const TickType_t xDelayTime = pdMS_TO_TICKS( 100UL );

	for( ;; )
	{
	#if defined ( __GNUC__ )
	{
	/* This task tests the kernel context switch mechanism by reading and
	writing directly to registers - which requires the test to be written
	in assembly code. */
	__asm volatile
	(
	" MOV R4, #4 \n" /* Set registers to a known value. R0 to R1 are done in the loop below. */
	" MOV R5, #5 \n"
	" MOV R6, #6 \n"
	" MOV R8, #8 \n" /* Frame pointer is omitted as it must not be changed. */
	" MOV R9, #9 \n"
	" MOV R10, 10 \n"
	" MOV R11, #11 \n"
	"reg2loop: \n"
	" MOV R0, #13 \n" /* Set the scratch registers to known values - done inside the loop as they get clobbered. */
	" MOV R1, #1 \n"
	" MOV R2, #2 \n"
	" MOV R3, #3 \n"
	" MOV R12, #12 \n"
	" CMP R0, #13 \n" /* Check all the registers still contain their expected values. */
	" BNE vMainDeleteMe \n" /* Value was not as expected, delete the task so it stops communicating with the check task */
	" CMP R1, #1 \n"
	" BNE vMainDeleteMe \n"
	" CMP R2, #2 \n"
	" BNE vMainDeleteMe \n"
	" CMP R3, #3 \n"
	" BNE vMainDeleteMe \n"
	" CMP R4, #4 \n"
	" BNE vMainDeleteMe \n"
	" CMP R5, #5 \n"
	" BNE vMainDeleteMe \n"
	" CMP R6, #6 \n"
	" BNE vMainDeleteMe \n"
	" CMP R8, #8 \n"
	" BNE vMainDeleteMe \n"
	" CMP R9, #9 \n"
	" BNE vMainDeleteMe \n"
	" CMP R10, #10 \n"
	" BNE vMainDeleteMe \n"
	" CMP R11, #11 \n"
	" BNE vMainDeleteMe \n"
	" CMP R12, #12 \n"
	" BNE vMainDeleteMe \n"
	:::"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r8", "r9", "r10", "r11", "r12"
	);
	}
	#endif /* __GNUC__ */

	/* Send configREG_TEST_2_STILL_EXECUTING to the check task to indicate
	that this task is still functioning. */
	vMainSendImAlive( xQueue, configREG_TEST_2_STILL_EXECUTING );
	vTaskDelay( xDelayTime );

	#if defined ( __GNUC__ )
	{
	/* Go back to check all the register values again. */
	__asm volatile( " B reg2loop " );
	}
	#endif /* __GNUC__ */
	}
	}
	/-----------------------------------------------------------/

	__asm void vRegTest3Implementation( void )
	{
	extern pulRegTest3LoopCounter

	PRESERVE8

	/* Fill the core registers with known values. */
	mov r0, #100
	mov r1, #101
	mov r2, #102
	mov r3, #103
	mov r4, #104
	mov r5, #105
	mov r6, #106
	mov r7, #107
	mov r8, #108
	mov r9, #109
	mov r10, #110
	mov r11, #111
	mov r12, #112

	/* Fill the VFP registers with known values. */
	vmov d0, r0, r1
	vmov d1, r2, r3
	vmov d2, r4, r5
	vmov d3, r6, r7
	vmov d4, r8, r9
	vmov d5, r10, r11
	vmov d6, r0, r1
	vmov d7, r2, r3
	vmov d8, r4, r5
	vmov d9, r6, r7
	vmov d10, r8, r9
	vmov d11, r10, r11
	vmov d12, r0, r1
	vmov d13, r2, r3
	vmov d14, r4, r5
	vmov d15, r6, r7

	reg1_loop

	/* Check all the VFP registers still contain the values set above.
	First save registers that are clobbered by the test. */
	push { r0-r1 }

	vmov r0, r1, d0
	cmp r0, #100
	bne reg1_error_loopf
	cmp r1, #101
	bne reg1_error_loopf
	vmov r0, r1, d1
	cmp r0, #102
	bne reg1_error_loopf
	cmp r1, #103
	bne reg1_error_loopf
	vmov r0, r1, d2
	cmp r0, #104
	bne reg1_error_loopf
	cmp r1, #105
	bne reg1_error_loopf
	vmov r0, r1, d3
	cmp r0, #106
	bne reg1_error_loopf
	cmp r1, #107
	bne reg1_error_loopf
	vmov r0, r1, d4
	cmp r0, #108
	bne reg1_error_loopf
	cmp r1, #109
	bne reg1_error_loopf
	vmov r0, r1, d5
	cmp r0, #110
	bne reg1_error_loopf
	cmp r1, #111
	bne reg1_error_loopf
	vmov r0, r1, d6
	cmp r0, #100
	bne reg1_error_loopf
	cmp r1, #101
	bne reg1_error_loopf
	vmov r0, r1, d7
	cmp r0, #102
	bne reg1_error_loopf
	cmp r1, #103
	bne reg1_error_loopf
	vmov r0, r1, d8
	cmp r0, #104
	bne reg1_error_loopf
	cmp r1, #105
	bne reg1_error_loopf
	vmov r0, r1, d9
	cmp r0, #106
	bne reg1_error_loopf
	cmp r1, #107
	bne reg1_error_loopf
	vmov r0, r1, d10
	cmp r0, #108
	bne reg1_error_loopf
	cmp r1, #109
	bne reg1_error_loopf
	vmov r0, r1, d11
	cmp r0, #110
	bne reg1_error_loopf
	cmp r1, #111
	bne reg1_error_loopf
	vmov r0, r1, d12
	cmp r0, #100
	bne reg1_error_loopf
	cmp r1, #101
	bne reg1_error_loopf
	vmov r0, r1, d13
	cmp r0, #102
	bne reg1_error_loopf
	cmp r1, #103
	bne reg1_error_loopf
	vmov r0, r1, d14
	cmp r0, #104
	bne reg1_error_loopf
	cmp r1, #105
	bne reg1_error_loopf
	vmov r0, r1, d15
	cmp r0, #106
	bne reg1_error_loopf
	cmp r1, #107
	bne reg1_error_loopf

	/* Restore the registers that were clobbered by the test. */
	pop {r0-r1}

	/* VFP register test passed. Jump to the core register test. */
	b reg1_loopf_pass

	reg1_error_loopf
	/* If this line is hit then a VFP register value was found to be incorrect. */
	b reg1_error_loopf

	reg1_loopf_pass

	cmp r0, #100
	bne reg1_error_loop
	cmp r1, #101
	bne reg1_error_loop
	cmp r2, #102
	bne reg1_error_loop
	cmp r3, #103
	bne reg1_error_loop
	cmp r4, #104
	bne reg1_error_loop
	cmp r5, #105
	bne reg1_error_loop
	cmp r6, #106
	bne reg1_error_loop
	cmp r7, #107
	bne reg1_error_loop
	cmp r8, #108
	bne reg1_error_loop
	cmp r9, #109
	bne reg1_error_loop
	cmp r10, #110
	bne reg1_error_loop
	cmp r11, #111
	bne reg1_error_loop
	cmp r12, #112
	bne reg1_error_loop

	/* Everything passed, increment the loop counter. */
	push { r0-r1 }
	ldr r0, =pulRegTest3LoopCounter
	ldr r0, [r0]
	ldr r1, [r0]
	adds r1, r1, #1
	str r1, [r0]
	pop { r0-r1 }

	/* Start again. */
	b reg1_loop

	reg1_error_loop
	/* If this line is hit then there was an error in a core register value.
	The loop ensures the loop counter stops incrementing. */
	b reg1_error_loop
	nop
	nop
	}
	/-----------------------------------------------------------/

	__asm void vRegTest4Implementation( void )
	{
	extern pulRegTest4LoopCounter;

	PRESERVE8

	/* Set all the core registers to known values. */
	mov r0, #-1
	mov r1, #1
	mov r2, #2
	mov r3, #3
	mov r4, #4
	mov r5, #5
	mov r6, #6
	mov r7, #7
	mov r8, #8
	mov r9, #9
	mov r10, #10
	mov r11, #11
	mov r12, #12

	/* Set all the VFP to known values. */
	vmov d0, r0, r1
	vmov d1, r2, r3
	vmov d2, r4, r5
	vmov d3, r6, r7
	vmov d4, r8, r9
	vmov d5, r10, r11
	vmov d6, r0, r1
	vmov d7, r2, r3
	vmov d8, r4, r5
	vmov d9, r6, r7
	vmov d10, r8, r9
	vmov d11, r10, r11
	vmov d12, r0, r1
	vmov d13, r2, r3
	vmov d14, r4, r5
	vmov d15, r6, r7

	reg2_loop

	/* Check all the VFP registers still contain the values set above.
	First save registers that are clobbered by the test. */
	push { r0-r1 }

	vmov r0, r1, d0
	cmp r0, #-1
	bne reg2_error_loopf
	cmp r1, #1
	bne reg2_error_loopf
	vmov r0, r1, d1
	cmp r0, #2
	bne reg2_error_loopf
	cmp r1, #3
	bne reg2_error_loopf
	vmov r0, r1, d2
	cmp r0, #4
	bne reg2_error_loopf
	cmp r1, #5
	bne reg2_error_loopf
	vmov r0, r1, d3
	cmp r0, #6
	bne reg2_error_loopf
	cmp r1, #7
	bne reg2_error_loopf
	vmov r0, r1, d4
	cmp r0, #8
	bne reg2_error_loopf
	cmp r1, #9
	bne reg2_error_loopf
	vmov r0, r1, d5
	cmp r0, #10
	bne reg2_error_loopf
	cmp r1, #11
	bne reg2_error_loopf
	vmov r0, r1, d6
	cmp r0, #-1
	bne reg2_error_loopf
	cmp r1, #1
	bne reg2_error_loopf
	vmov r0, r1, d7
	cmp r0, #2
	bne reg2_error_loopf
	cmp r1, #3
	bne reg2_error_loopf
	vmov r0, r1, d8
	cmp r0, #4
	bne reg2_error_loopf
	cmp r1, #5
	bne reg2_error_loopf
	vmov r0, r1, d9
	cmp r0, #6
	bne reg2_error_loopf
	cmp r1, #7
	bne reg2_error_loopf
	vmov r0, r1, d10
	cmp r0, #8
	bne reg2_error_loopf
	cmp r1, #9
	bne reg2_error_loopf
	vmov r0, r1, d11
	cmp r0, #10
	bne reg2_error_loopf
	cmp r1, #11
	bne reg2_error_loopf
	vmov r0, r1, d12
	cmp r0, #-1
	bne reg2_error_loopf
	cmp r1, #1
	bne reg2_error_loopf
	vmov r0, r1, d13
	cmp r0, #2
	bne reg2_error_loopf
	cmp r1, #3
	bne reg2_error_loopf
	vmov r0, r1, d14
	cmp r0, #4
	bne reg2_error_loopf
	cmp r1, #5
	bne reg2_error_loopf
	vmov r0, r1, d15
	cmp r0, #6
	bne reg2_error_loopf
	cmp r1, #7
	bne reg2_error_loopf

	/* Restore the registers that were clobbered by the test. */
	pop {r0-r1}

	/* VFP register test passed. Jump to the core register test. */
	b reg2_loopf_pass

	reg2_error_loopf
	/* If this line is hit then a VFP register value was found to be
	incorrect. */
	b reg2_error_loopf

	reg2_loopf_pass

	cmp r0, #-1
	bne reg2_error_loop
	cmp r1, #1
	bne reg2_error_loop
	cmp r2, #2
	bne reg2_error_loop
	cmp r3, #3
	bne reg2_error_loop
	cmp r4, #4
	bne reg2_error_loop
	cmp r5, #5
	bne reg2_error_loop
	cmp r6, #6
	bne reg2_error_loop
	cmp r7, #7
	bne reg2_error_loop
	cmp r8, #8
	bne reg2_error_loop
	cmp r9, #9
	bne reg2_error_loop
	cmp r10, #10
	bne reg2_error_loop
	cmp r11, #11
	bne reg2_error_loop
	cmp r12, #12
	bne reg2_error_loop

	/* Increment the loop counter so the check task knows this task is
	still running. */
	push { r0-r1 }
	ldr r0, =pulRegTest4LoopCounter
	ldr r0, [r0]
	ldr r1, [r0]
	adds r1, r1, #1
	str r1, [r0]
	pop { r0-r1 }

	/* Yield to increase test coverage. */
	SVC #1

	/* Start again. */
	b reg2_loop

	reg2_error_loop
	/* If this line is hit then there was an error in a core register value.
	This loop ensures the loop counter variable stops incrementing. */
	b reg2_error_loop
	nop
	}
	/-----------------------------------------------------------/

	/* Fault handlers are here for convenience as they use compiler specific syntax
	and this file is specific to the Keil compiler. */
	void hard_fault_handler( uint32_t * hardfault_args )
	{
	volatile uint32_t stacked_r0;
	volatile uint32_t stacked_r1;
	volatile uint32_t stacked_r2;
	volatile uint32_t stacked_r3;
	volatile uint32_t stacked_r12;
	volatile uint32_t stacked_lr;
	volatile uint32_t stacked_pc;
	volatile uint32_t stacked_psr;

	stacked_r0 = ((uint32_t) hardfault_args[ 0 ]);
	stacked_r1 = ((uint32_t) hardfault_args[ 1 ]);
	stacked_r2 = ((uint32_t) hardfault_args[ 2 ]);
	stacked_r3 = ((uint32_t) hardfault_args[ 3 ]);

	stacked_r12 = ((uint32_t) hardfault_args[ 4 ]);
	stacked_lr = ((uint32_t) hardfault_args[ 5 ]);
	stacked_pc = ((uint32_t) hardfault_args[ 6 ]);
	stacked_psr = ((uint32_t) hardfault_args[ 7 ]);

	/* Inspect stacked_pc to locate the offending instruction. */
	for( ;; );
	}
	/-----------------------------------------------------------/

	void HardFault_Handler( void );
	__asm void HardFault_Handler( void )
	{
	extern hard_fault_handler

	tst lr, #4
	ite eq
	mrseq r0, msp
	mrsne r0, psp
	ldr r1, [r0, #24]
	ldr r2, hard_fault_handler
	bx r2
	}
	/-----------------------------------------------------------/

	void MemManage_Handler( void );
	__asm void MemManage_Handler( void )
	{
	extern hard_fault_handler

	tst lr, #4
	ite eq
	mrseq r0, msp
	mrsne r0, psp
	ldr r1, [r0, #24]
	ldr r2, hard_fault_handler
	bx r2
	}
	/-----------------------------------------------------------/