Demo/MicroBlaze_Spartan-6_EthernetLite/SDKProjects/RTOSDemo/RegisterTests.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /*
     FreeRTOS V7.0.2 - Copyright (C) 2011 Real Time Engineers Ltd.


     ***************************************************************************
      *                                                                       *
      *    FreeRTOS tutorial books are available in pdf and paperback.        *
      *    Complete, revised, and edited pdf reference manuals are also       *
      *    available.                                                         *
      *                                                                       *
      *    Purchasing FreeRTOS documentation will not only help you, by       *
      *    ensuring you get running as quickly as possible and with an        *
      *    in-depth knowledge of how to use FreeRTOS, it will also help       *
      *    the FreeRTOS project to continue with its mission of providing     *
      *    professional grade, cross platform, de facto standard solutions    *
      *    for microcontrollers - completely free of charge!                  *
      *                                                                       *
      *    >>> See http://www.FreeRTOS.org/Documentation for details. <<<     *
      *                                                                       *
      *    Thank you for using FreeRTOS, and thank you for your support!      *
      *                                                                       *
     ***************************************************************************


     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.  See the GNU General Public License for
     more details. You should have received a copy of the GNU General Public
     License and the FreeRTOS license exception along with FreeRTOS; if not it
     can be viewed here: http://www.freertos.org/a00114.html and also obtained
     by writing to Richard Barry, contact details for whom are available on the
     FreeRTOS WEB site.

     1 tab == 4 spaces!

     http://www.FreeRTOS.org - Documentation, latest information, license and
     contact details.

     http://www.SafeRTOS.com - A version that is certified for use in safety
     critical systems.

     http://www.OpenRTOS.com - Commercial support, development, porting,
     licensing and training services.
 */

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

 /*
  * The register test task as described in the comments at the top of main-full.c.
  */
 void vRegisterTest1( void *pvParameters );
 void vRegisterTest2( void *pvParameters );

 /* Variables that are incremented on each iteration of the reg test tasks -
 provided the tasks have not reported any errors.  The check timer inspects these
 variables to ensure they are still incrementing as expected.  If a variable
 stops incrementing then it is likely that its associate task has stalled or
 detected an error. */
 volatile unsigned long ulRegTest1CycleCount = 0UL, ulRegTest2CycleCount = 0UL;

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

 void vRegisterTest1( void *pvParameters )
 {
 	/* This task uses an infinite loop that is implemented in the assembly
 	code.

 	First fill the relevant registers with known values. */
 	asm volatile (	"	addi r3, r0, 3		\n\t" \
 					"	addi r4, r0, 4		\n\t" \
 					"	addi r6, r0, 6		\n\t" \
 					"	addi r7, r0, 7		\n\t" \
 					"	addi r8, r0, 8		\n\t" \
 					"	addi r9, r0, 9		\n\t" \
 					"	addi r10, r0, 10	\n\t" \
 					"	addi r11, r0, 11	\n\t" \
 					"	addi r12, r0, 12	\n\t" \
 					"	addi r16, r0, 16	\n\t" \
 					"	addi r19, r0, 19	\n\t" \
 					"	addi r20, r0, 20	\n\t" \
 					"	addi r21, r0, 21	\n\t" \
 					"	addi r22, r0, 22	\n\t" \
 					"	addi r23, r0, 23	\n\t" \
 					"	addi r24, r0, 24	\n\t" \
 					"	addi r25, r0, 25	\n\t" \
 					"	addi r26, r0, 26	\n\t" \
 					"	addi r27, r0, 27	\n\t" \
 					"	addi r28, r0, 28	\n\t" \
 					"	addi r29, r0, 29	\n\t" \
 					"	addi r30, r0, 30	\n\t" \
 					"	addi r31, r0, 31	\n\t"
 				);

 	/* Now test the register values to ensure they contain the same value that
 	was written to them above.	 This task will get preempted frequently so
 	other tasks are likely to have executed since the register values were
 	written.  If any register contains an unexpected value then the task will
 	branch to Error_Loop_1, which in turn prevents it from incrementing its
 	loop counter, enabling the check timer to determine that all is not as it
 	should be. */

 	asm volatile (	"Loop_Start_1:				\n\t" \
 					"	xori r18, r3, 3			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r4, 4			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r6, 6			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r7, 7			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r8, 8			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r9, 9			\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r10, 10		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r11, 11		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r12, 12		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r16, 16		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r19, 19		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r20, 20		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r21, 21		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r22, 22		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r23, 23		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r24, 24		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r25, 25		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r26, 26		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r27, 27		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r28, 28		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r29, 29		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r30, 30		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t" \
 					"	xori r18, r31, 31		\n\t" \
 					"	bnei r18, Error_Loop_1	\n\t"
 				 );

 	/* If this task has not branched to the error loop, then everything is ok,
 	and the check variable can be incremented to indicate that this task
 	is still running.  Then, brach back to the top to check the register
 	contents again. */
 	asm volatile (  "	lwi r18, r0, ulRegTest1CycleCount	\n\t" \
 					"	addik r18, r18, 1			 		\n\t" \
 					"	swi r18, r0, ulRegTest1CycleCount 	\n\t" \
 					"										\n\t" \
 					"	bri Loop_Start_1 "
 				 );

 	 /* The test function will branch here if it discovers an error.  This part
 	of the code just sits in a NULL loop, which prevents the check variable
 	incrementing any further to allow the check timer to recognize that this
 	test has failed. */
 	asm volatile (	"Error_Loop_1:			\n\t" \
 					"	bri 0				\n\t" \
 					"	nop					\n\t" \
 				 );

 	( void ) pvParameters;
 }
 /*-----------------------------------------------------------*/

 void vRegisterTest2( void *pvParameters )
 {
 	/* This task uses an infinite loop that is implemented in the assembly
 	code.

 	First fill the registers with known values. */
 	asm volatile (	"	addi r16, r0, 1016	\n\t" \
 					"	addi r19, r0, 1019	\n\t" \
 					"	addi r20, r0, 1020	\n\t" \
 					"	addi r21, r0, 1021	\n\t" \
 					"	addi r22, r0, 1022	\n\t" \
 					"	addi r23, r0, 1023	\n\t" \
 					"	addi r24, r0, 1024	\n\t" \
 					"	addi r25, r0, 1025	\n\t" \
 					"	addi r26, r0, 1026	\n\t" \
 					"	addi r27, r0, 1027	\n\t" \
 					"	addi r28, r0, 1028	\n\t" \
 					"	addi r29, r0, 1029	\n\t" \
 					"	addi r30, r0, 1030	\n\t" \
 					"	addi r31, r0, 1031	\n\t" \
 					"							" \
 					"Loop_Start_2:				"
 				);

 	/* Unlike vRegisterTest1, vRegisterTest2 performs a yield.  This increases
 	the test coverage, but does mean volatile registers need re-loading with
 	their exepcted values. */
 	taskYIELD();

 	/* taskYIELD() could have changed temporaries - set them back to those
 	expected by the reg test task. */
 	asm volatile (  "	addi r3, r0, 103	\n\t" \
 					"	addi r4, r0, 104	\n\t" \
 					"	addi r6, r0, 106	\n\t" \
 					"	addi r7, r0, 107	\n\t" \
 					"	addi r8, r0, 108	\n\t" \
 					"	addi r9, r0, 109	\n\t" \
 					"	addi r10, r0, 1010	\n\t" \
 					"	addi r11, r0, 1011	\n\t" \
 					"	addi r12, r0, 1012	\n\t" \
 				);


 	/* Now test the register values to ensure they contain the same value that
 	was written to them above.	 This task will get preempted frequently so
 	other tasks are likely to have executed since the register values were
 	written. */
 	asm volatile (	"	xori r18, r3, 103		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r4, 104		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r6, 106		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r7, 107		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r8, 108		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r9, 109		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r10, 1010		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r11, 1011		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r12, 1012		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r16, 1016		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r19, 1019		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r20, 1020		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r21, 1021		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r22, 1022		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r23, 1023		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r24, 1024		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r25, 1025		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r26, 1026		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r27, 1027		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r28, 1028		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r29, 1029		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r30, 1030		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t" \
 					"	xori r18, r31, 1031		\n\t" \
 					"	bnei r18, Error_Loop_2	\n\t"
 				 );

 	/* If this task has not branched to the error loop, then everything is ok,
 	and the check variable should be incremented to indicate that this task
 	is still running.  Then, brach back to the top to check the registers
 	again. */
 	asm volatile (  "	lwi r18, r0, ulRegTest2CycleCount	\n\t" \
 					"	addik r18, r18, 1			 		\n\t" \
 					"	swi r18, r0, ulRegTest2CycleCount 	\n\t" \
 					"										\n\t" \
 					"	bri Loop_Start_2 "
 				 );

 	 /* The test function will branch here if it discovers an error.  This part
 	of the code just sits in a NULL loop, which prevents the check variable
 	incrementing any further to allow the check timer to recognize that this
 	test has failed. */
 	asm volatile (	"Error_Loop_2:			\n\t" \
 					"	bri 0				\n\t" \
 					"	nop					\n\t" \
 				 );

 	( void ) pvParameters;
 }
	/*
	FreeRTOS V7.0.2 - Copyright (C) 2011 Real Time Engineers Ltd.


	***************************************************************************
	* *
	* FreeRTOS tutorial books are available in pdf and paperback. *
	* Complete, revised, and edited pdf reference manuals are also *
	* available. *
	* *
	* Purchasing FreeRTOS documentation will not only help you, by *
	* ensuring you get running as quickly as possible and with an *
	* in-depth knowledge of how to use FreeRTOS, it will also help *
	* the FreeRTOS project to continue with its mission of providing *
	* professional grade, cross platform, de facto standard solutions *
	* for microcontrollers - completely free of charge! *
	* *
	* >>> See http://www.FreeRTOS.org/Documentation for details. <<< *
	* *
	* Thank you for using FreeRTOS, and thank you for your support! *
	* *
	***************************************************************************


	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. See the GNU General Public License for
	more details. You should have received a copy of the GNU General Public
	License and the FreeRTOS license exception along with FreeRTOS; if not it
	can be viewed here: http://www.freertos.org/a00114.html and also obtained
	by writing to Richard Barry, contact details for whom are available on the
	FreeRTOS WEB site.

	1 tab == 4 spaces!

	http://www.FreeRTOS.org - Documentation, latest information, license and
	contact details.

	http://www.SafeRTOS.com - A version that is certified for use in safety
	critical systems.

	http://www.OpenRTOS.com - Commercial support, development, porting,
	licensing and training services.
	*/

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

	/*
	* The register test task as described in the comments at the top of main-full.c.
	*/
	void vRegisterTest1( void *pvParameters );
	void vRegisterTest2( void *pvParameters );

	/* Variables that are incremented on each iteration of the reg test tasks -
	provided the tasks have not reported any errors. The check timer inspects these
	variables to ensure they are still incrementing as expected. If a variable
	stops incrementing then it is likely that its associate task has stalled or
	detected an error. */
	volatile unsigned long ulRegTest1CycleCount = 0UL, ulRegTest2CycleCount = 0UL;

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

	void vRegisterTest1( void *pvParameters )
	{
	/* This task uses an infinite loop that is implemented in the assembly
	code.

	First fill the relevant registers with known values. */
	asm volatile ( " addi r3, r0, 3 \n\t" \
	" addi r4, r0, 4 \n\t" \
	" addi r6, r0, 6 \n\t" \
	" addi r7, r0, 7 \n\t" \
	" addi r8, r0, 8 \n\t" \
	" addi r9, r0, 9 \n\t" \
	" addi r10, r0, 10 \n\t" \
	" addi r11, r0, 11 \n\t" \
	" addi r12, r0, 12 \n\t" \
	" addi r16, r0, 16 \n\t" \
	" addi r19, r0, 19 \n\t" \
	" addi r20, r0, 20 \n\t" \
	" addi r21, r0, 21 \n\t" \
	" addi r22, r0, 22 \n\t" \
	" addi r23, r0, 23 \n\t" \
	" addi r24, r0, 24 \n\t" \
	" addi r25, r0, 25 \n\t" \
	" addi r26, r0, 26 \n\t" \
	" addi r27, r0, 27 \n\t" \
	" addi r28, r0, 28 \n\t" \
	" addi r29, r0, 29 \n\t" \
	" addi r30, r0, 30 \n\t" \
	" addi r31, r0, 31 \n\t"
	);

	/* Now test the register values to ensure they contain the same value that
	was written to them above. This task will get preempted frequently so
	other tasks are likely to have executed since the register values were
	written. If any register contains an unexpected value then the task will
	branch to Error_Loop_1, which in turn prevents it from incrementing its
	loop counter, enabling the check timer to determine that all is not as it
	should be. */

	asm volatile ( "Loop_Start_1: \n\t" \
	" xori r18, r3, 3 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r4, 4 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r6, 6 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r7, 7 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r8, 8 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r9, 9 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r10, 10 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r11, 11 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r12, 12 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r16, 16 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r19, 19 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r20, 20 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r21, 21 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r22, 22 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r23, 23 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r24, 24 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r25, 25 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r26, 26 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r27, 27 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r28, 28 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r29, 29 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r30, 30 \n\t" \
	" bnei r18, Error_Loop_1 \n\t" \
	" xori r18, r31, 31 \n\t" \
	" bnei r18, Error_Loop_1 \n\t"
	);

	/* If this task has not branched to the error loop, then everything is ok,
	and the check variable can be incremented to indicate that this task
	is still running. Then, brach back to the top to check the register
	contents again. */
	asm volatile ( " lwi r18, r0, ulRegTest1CycleCount \n\t" \
	" addik r18, r18, 1 \n\t" \
	" swi r18, r0, ulRegTest1CycleCount \n\t" \
	" \n\t" \
	" bri Loop_Start_1 "
	);

	/* The test function will branch here if it discovers an error. This part
	of the code just sits in a NULL loop, which prevents the check variable
	incrementing any further to allow the check timer to recognize that this
	test has failed. */
	asm volatile ( "Error_Loop_1: \n\t" \
	" bri 0 \n\t" \
	" nop \n\t" \
	);

	( void ) pvParameters;
	}
	/-----------------------------------------------------------/

	void vRegisterTest2( void *pvParameters )
	{
	/* This task uses an infinite loop that is implemented in the assembly
	code.

	First fill the registers with known values. */
	asm volatile ( " addi r16, r0, 1016 \n\t" \
	" addi r19, r0, 1019 \n\t" \
	" addi r20, r0, 1020 \n\t" \
	" addi r21, r0, 1021 \n\t" \
	" addi r22, r0, 1022 \n\t" \
	" addi r23, r0, 1023 \n\t" \
	" addi r24, r0, 1024 \n\t" \
	" addi r25, r0, 1025 \n\t" \
	" addi r26, r0, 1026 \n\t" \
	" addi r27, r0, 1027 \n\t" \
	" addi r28, r0, 1028 \n\t" \
	" addi r29, r0, 1029 \n\t" \
	" addi r30, r0, 1030 \n\t" \
	" addi r31, r0, 1031 \n\t" \
	" " \
	"Loop_Start_2: "
	);

	/* Unlike vRegisterTest1, vRegisterTest2 performs a yield. This increases
	the test coverage, but does mean volatile registers need re-loading with
	their exepcted values. */
	taskYIELD();

	/* taskYIELD() could have changed temporaries - set them back to those
	expected by the reg test task. */
	asm volatile ( " addi r3, r0, 103 \n\t" \
	" addi r4, r0, 104 \n\t" \
	" addi r6, r0, 106 \n\t" \
	" addi r7, r0, 107 \n\t" \
	" addi r8, r0, 108 \n\t" \
	" addi r9, r0, 109 \n\t" \
	" addi r10, r0, 1010 \n\t" \
	" addi r11, r0, 1011 \n\t" \
	" addi r12, r0, 1012 \n\t" \
	);


	/* Now test the register values to ensure they contain the same value that
	was written to them above. This task will get preempted frequently so
	other tasks are likely to have executed since the register values were
	written. */
	asm volatile ( " xori r18, r3, 103 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r4, 104 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r6, 106 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r7, 107 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r8, 108 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r9, 109 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r10, 1010 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r11, 1011 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r12, 1012 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r16, 1016 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r19, 1019 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r20, 1020 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r21, 1021 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r22, 1022 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r23, 1023 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r24, 1024 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r25, 1025 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r26, 1026 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r27, 1027 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r28, 1028 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r29, 1029 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r30, 1030 \n\t" \
	" bnei r18, Error_Loop_2 \n\t" \
	" xori r18, r31, 1031 \n\t" \
	" bnei r18, Error_Loop_2 \n\t"
	);

	/* If this task has not branched to the error loop, then everything is ok,
	and the check variable should be incremented to indicate that this task
	is still running. Then, brach back to the top to check the registers
	again. */
	asm volatile ( " lwi r18, r0, ulRegTest2CycleCount \n\t" \
	" addik r18, r18, 1 \n\t" \
	" swi r18, r0, ulRegTest2CycleCount \n\t" \
	" \n\t" \
	" bri Loop_Start_2 "
	);

	/* The test function will branch here if it discovers an error. This part
	of the code just sits in a NULL loop, which prevents the check variable
	incrementing any further to allow the check timer to recognize that this
	test has failed. */
	asm volatile ( "Error_Loop_2: \n\t" \
	" bri 0 \n\t" \
	" nop \n\t" \
	);

	( void ) pvParameters;
	}