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/*

    FreeRTOS V6.1.1 - Copyright (C) 2011 Real Time Engineers Ltd.

    ***************************************************************************

    *                                                                         *

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    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 exception to the GPL is included to allow you to distribute

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*/

#ifndef INC_FREERTOS_H

        #error "include FreeRTOS.h must appear in source files before include task.h"

#endif

#ifndef TASK_H

#define TASK_H

#include "portable.h"

#include "list.h"

#ifdef __cplusplus

extern "C" {

#endif

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

 * MACROS AND DEFINITIONS

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

#define tskKERNEL_VERSION_NUMBER "V6.1.1"

/**

 * task. h

 *

 * Type by which tasks are referenced.  For example, a call to xTaskCreate

 * returns (via a pointer parameter) an xTaskHandle variable that can then

 * be used as a parameter to vTaskDelete to delete the task.

 *

 * \page xTaskHandle xTaskHandle

 * \ingroup Tasks

 */

typedef void * xTaskHandle;

/*

 * Used internally only.

 */

typedef struct xTIME_OUT

{

        portBASE_TYPE xOverflowCount;

        portTickType  xTimeOnEntering;

} xTimeOutType;

/*

 * Defines the memory ranges allocated to the task when an MPU is used.

 */

typedef struct xMEMORY_REGION

{

        void *pvBaseAddress;

        unsigned long ulLengthInBytes;

        unsigned long ulParameters;

} xMemoryRegion;

/*

 * Parameters required to create an MPU protected task.

 */

typedef struct xTASK_PARAMTERS

{

        pdTASK_CODE pvTaskCode;

        const signed char * const pcName;

        unsigned short usStackDepth;

        void *pvParameters;

        unsigned portBASE_TYPE uxPriority;

        portSTACK_TYPE *puxStackBuffer;

        xMemoryRegion xRegions[ portNUM_CONFIGURABLE_REGIONS ];

} xTaskParameters;

/*

 * Defines the priority used by the idle task.  This must not be modified.

 *

 * \ingroup TaskUtils

 */

#define tskIDLE_PRIORITY                        ( ( unsigned portBASE_TYPE ) 0 )

/**

 * task. h

 *

 * Macro for forcing a context switch.

 *

 * \page taskYIELD taskYIELD

 * \ingroup SchedulerControl

 */

#define taskYIELD()                                     portYIELD()

/**

 * task. h

 *

 * Macro to mark the start of a critical code region.  Preemptive context

 * switches cannot occur when in a critical region.

 *

 * NOTE: This may alter the stack (depending on the portable implementation)

 * so must be used with care!

 *

 * \page taskENTER_CRITICAL taskENTER_CRITICAL

 * \ingroup SchedulerControl

 */

#define taskENTER_CRITICAL()            portENTER_CRITICAL()

/**

 * task. h

 *

 * Macro to mark the end of a critical code region.  Preemptive context

 * switches cannot occur when in a critical region.

 *

 * NOTE: This may alter the stack (depending on the portable implementation)

 * so must be used with care!

 *

 * \page taskEXIT_CRITICAL taskEXIT_CRITICAL

 * \ingroup SchedulerControl

 */

#define taskEXIT_CRITICAL()                     portEXIT_CRITICAL()

/**

 * task. h

 *

 * Macro to disable all maskable interrupts.

 *

 * \page taskDISABLE_INTERRUPTS taskDISABLE_INTERRUPTS

 * \ingroup SchedulerControl

 */

#define taskDISABLE_INTERRUPTS()        portDISABLE_INTERRUPTS()

/**

 * task. h

 *

 * Macro to enable microcontroller interrupts.

 *

 * \page taskENABLE_INTERRUPTS taskENABLE_INTERRUPTS

 * \ingroup SchedulerControl

 */

#define taskENABLE_INTERRUPTS()         portENABLE_INTERRUPTS()

/* Definitions returned by xTaskGetSchedulerState(). */

#define taskSCHEDULER_NOT_STARTED       0

#define taskSCHEDULER_RUNNING           1

#define taskSCHEDULER_SUSPENDED         2

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

 * TASK CREATION API

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

/**

 * task. h

 *<pre>

 portBASE_TYPE xTaskCreate(

                                                          pdTASK_CODE pvTaskCode,

                                                          const char * const pcName,

                                                          unsigned short usStackDepth,

                                                          void *pvParameters,

                                                          unsigned portBASE_TYPE uxPriority,

                                                          xTaskHandle *pvCreatedTask

                                                  );</pre>

 *

 * Create a new task and add it to the list of tasks that are ready to run.

 *

 * xTaskCreate() can only be used to create a task that has unrestricted

 * access to the entire microcontroller memory map.  Systems that include MPU

 * support can alternatively create an MPU constrained task using

 * xTaskCreateRestricted().

 *

 * @param pvTaskCode Pointer to the task entry function.  Tasks

 * must be implemented to never return (i.e. continuous loop).

 *

 * @param pcName A descriptive name for the task.  This is mainly used to

 * facilitate debugging.  Max length defined by tskMAX_TASK_NAME_LEN - default

 * is 16.

 *

 * @param usStackDepth The size of the task stack specified as the number of

 * variables the stack can hold - not the number of bytes.  For example, if

 * the stack is 16 bits wide and usStackDepth is defined as 100, 200 bytes

 * will be allocated for stack storage.

 *

 * @param pvParameters Pointer that will be used as the parameter for the task

 * being created.

 *

 * @param uxPriority The priority at which the task should run.  Systems that

 * include MPU support can optionally create tasks in a privileged (system)

 * mode by setting bit portPRIVILEGE_BIT of the priority parameter.  For

 * example, to create a privileged task at priority 2 the uxPriority parameter

 * should be set to ( 2 | portPRIVILEGE_BIT ).

 *

 * @param pvCreatedTask Used to pass back a handle by which the created task

 * can be referenced.

 *

 * @return pdPASS if the task was successfully created and added to a ready

 * list, otherwise an error code defined in the file errors. h

 *

 * Example usage:

   <pre>

 // Task to be created.

 void vTaskCode( void * pvParameters )

 {

         for( ;; )

         {

                 // Task code goes here.

         }

 }

 // Function that creates a task.

 void vOtherFunction( void )

 {

 static unsigned char ucParameterToPass;

 xTaskHandle xHandle;

         // Create the task, storing the handle.  Note that the passed parameter ucParameterToPass

         // must exist for the lifetime of the task, so in this case is declared static.  If it was just an

         // an automatic stack variable it might no longer exist, or at least have been corrupted, by the time

         // the new task attempts to access it.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, &ucParameterToPass, tskIDLE_PRIORITY, &xHandle );

         // Use the handle to delete the task.

         vTaskDelete( xHandle );

 }

   </pre>

 * \defgroup xTaskCreate xTaskCreate

 * \ingroup Tasks

 */

#define xTaskCreate( pvTaskCode, pcName, usStackDepth, pvParameters, uxPriority, pxCreatedTask ) xTaskGenericCreate( ( pvTaskCode ), ( pcName ), ( usStackDepth ), ( pvParameters ), ( uxPriority ), ( pxCreatedTask ), ( NULL ), ( NULL ) )

/**

 * task. h

 *<pre>

 portBASE_TYPE xTaskCreateRestricted( xTaskParameters *pxTaskDefinition, xTaskHandle *pxCreatedTask );</pre>

 *

 * xTaskCreateRestricted() should only be used in systems that include an MPU

 * implementation.

 *

 * Create a new task and add it to the list of tasks that are ready to run.

 * The function parameters define the memory regions and associated access

 * permissions allocated to the task.

 *

 * @param pxTaskDefinition Pointer to a structure that contains a member

 * for each of the normal xTaskCreate() parameters (see the xTaskCreate() API

 * documentation) plus an optional stack buffer and the memory region

 * definitions.

 *

 * @param pxCreatedTask Used to pass back a handle by which the created task

 * can be referenced.

 *

 * @return pdPASS if the task was successfully created and added to a ready

 * list, otherwise an error code defined in the file errors. h

 *

 * Example usage:

   <pre>

// Create an xTaskParameters structure that defines the task to be created.

static const xTaskParameters xCheckTaskParameters =

{

        vATask,         // pvTaskCode - the function that implements the task.

        "ATask",        // pcName - just a text name for the task to assist debugging.

        100,            // usStackDepth - the stack size DEFINED IN WORDS.

        NULL,           // pvParameters - passed into the task function as the function parameters.

        ( 1UL | portPRIVILEGE_BIT ),// uxPriority - task priority, set the portPRIVILEGE_BIT if the task should run in a privileged state.

        cStackBuffer,// puxStackBuffer - the buffer to be used as the task stack.

        // xRegions - Allocate up to three separate memory regions for access by

        // the task, with appropriate access permissions.  Different processors have

        // different memory alignment requirements - refer to the FreeRTOS documentation

        // for full information.

        {

                // Base address                                 Length  Parameters

        { cReadWriteArray,                              32,             portMPU_REGION_READ_WRITE },

        { cReadOnlyArray,                               32,             portMPU_REGION_READ_ONLY },

        { cPrivilegedOnlyAccessArray,   128,    portMPU_REGION_PRIVILEGED_READ_WRITE }

        }

};

int main( void )

{

xTaskHandle xHandle;

        // Create a task from the const structure defined above.  The task handle

        // is requested (the second parameter is not NULL) but in this case just for

        // demonstration purposes as its not actually used.

        xTaskCreateRestricted( &xRegTest1Parameters, &xHandle );

        // Start the scheduler.

        vTaskStartScheduler();

        // Will only get here if there was insufficient memory to create the idle

        // task.

        for( ;; );

}

   </pre>

 * \defgroup xTaskCreateRestricted xTaskCreateRestricted

 * \ingroup Tasks

 */

#define xTaskCreateRestricted( x, pxCreatedTask ) xTaskGenericCreate( ((x)->pvTaskCode), ((x)->pcName), ((x)->usStackDepth), ((x)->pvParameters), ((x)->uxPriority), (pxCreatedTask), ((x)->puxStackBuffer), ((x)->xRegions) )

/**

 * task. h

 *<pre>

 void vTaskAllocateMPURegions( xTaskHandle xTask, const xMemoryRegion * const pxRegions );</pre>

 *

 * Memory regions are assigned to a restricted task when the task is created by

 * a call to xTaskCreateRestricted().  These regions can be redefined using

 * vTaskAllocateMPURegions().

 *

 * @param xTask The handle of the task being updated.

 *

 * @param xRegions A pointer to an xMemoryRegion structure that contains the

 * new memory region definitions.

 *

 * Example usage:

   <pre>

// Define an array of xMemoryRegion structures that configures an MPU region

// allowing read/write access for 1024 bytes starting at the beginning of the

// ucOneKByte array.  The other two of the maximum 3 definable regions are

// unused so set to zero.

static const xMemoryRegion xAltRegions[ portNUM_CONFIGURABLE_REGIONS ] =

{

        // Base address         Length          Parameters

        { ucOneKByte,           1024,           portMPU_REGION_READ_WRITE },

        { 0,                            0,                      0 },

        { 0,                            0,                      0 }

};

void vATask( void *pvParameters )

{

        // This task was created such that it has access to certain regions of

        // memory as defined by the MPU configuration.  At some point it is

        // desired that these MPU regions are replaced with that defined in the

        // xAltRegions const struct above.  Use a call to vTaskAllocateMPURegions()

        // for this purpose.  NULL is used as the task handle to indicate that this

        // function should modify the MPU regions of the calling task.

        vTaskAllocateMPURegions( NULL, xAltRegions );

        // Now the task can continue its function, but from this point on can only

        // access its stack and the ucOneKByte array (unless any other statically

        // defined or shared regions have been declared elsewhere).

}

   </pre>

 * \defgroup xTaskCreateRestricted xTaskCreateRestricted

 * \ingroup Tasks

 */

void vTaskAllocateMPURegions( xTaskHandle xTask, const xMemoryRegion * const pxRegions ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskDelete( xTaskHandle pxTask );</pre>

 *

 * INCLUDE_vTaskDelete must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Remove a task from the RTOS real time kernels management.  The task being

 * deleted will be removed from all ready, blocked, suspended and event lists.

 *

 * NOTE:  The idle task is responsible for freeing the kernel allocated

 * memory from tasks that have been deleted.  It is therefore important that

 * the idle task is not starved of microcontroller processing time if your

 * application makes any calls to vTaskDelete ().  Memory allocated by the

 * task code is not automatically freed, and should be freed before the task

 * is deleted.

 *

 * See the demo application file death.c for sample code that utilises

 * vTaskDelete ().

 *

 * @param pxTask The handle of the task to be deleted.  Passing NULL will

 * cause the calling task to be deleted.

 *

 * Example usage:

   <pre>

 void vOtherFunction( void )

 {

 xTaskHandle xHandle;

         // Create the task, storing the handle.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, &xHandle );

         // Use the handle to delete the task.

         vTaskDelete( xHandle );

 }

   </pre>

 * \defgroup vTaskDelete vTaskDelete

 * \ingroup Tasks

 */

void vTaskDelete( xTaskHandle pxTask ) PRIVILEGED_FUNCTION;

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

 * TASK CONTROL API

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

/**

 * task. h

 * <pre>void vTaskDelay( portTickType xTicksToDelay );</pre>

 *

 * Delay a task for a given number of ticks.  The actual time that the

 * task remains blocked depends on the tick rate.  The constant

 * portTICK_RATE_MS can be used to calculate real time from the tick

 * rate - with the resolution of one tick period.

 *

 * INCLUDE_vTaskDelay must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 *

 * vTaskDelay() specifies a time at which the task wishes to unblock relative to

 * the time at which vTaskDelay() is called.  For example, specifying a block

 * period of 100 ticks will cause the task to unblock 100 ticks after

 * vTaskDelay() is called.  vTaskDelay() does not therefore provide a good method

 * of controlling the frequency of a cyclical task as the path taken through the

 * code, as well as other task and interrupt activity, will effect the frequency

 * at which vTaskDelay() gets called and therefore the time at which the task

 * next executes.  See vTaskDelayUntil() for an alternative API function designed

 * to facilitate fixed frequency execution.  It does this by specifying an

 * absolute time (rather than a relative time) at which the calling task should

 * unblock.

 *

 * @param xTicksToDelay The amount of time, in tick periods, that

 * the calling task should block.

 *

 * Example usage:

 void vTaskFunction( void * pvParameters )

 {

 void vTaskFunction( void * pvParameters )

 {

 // Block for 500ms.

 const portTickType xDelay = 500 / portTICK_RATE_MS;

         for( ;; )

         {

                 // Simply toggle the LED every 500ms, blocking between each toggle.

                 vToggleLED();

                 vTaskDelay( xDelay );

         }

 }

 * \defgroup vTaskDelay vTaskDelay

 * \ingroup TaskCtrl

 */

void vTaskDelay( portTickType xTicksToDelay ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskDelayUntil( portTickType *pxPreviousWakeTime, portTickType xTimeIncrement );</pre>

 *

 * INCLUDE_vTaskDelayUntil must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Delay a task until a specified time.  This function can be used by cyclical

 * tasks to ensure a constant execution frequency.

 *

 * This function differs from vTaskDelay () in one important aspect:  vTaskDelay () will

 * cause a task to block for the specified number of ticks from the time vTaskDelay () is

 * called.  It is therefore difficult to use vTaskDelay () by itself to generate a fixed

 * execution frequency as the time between a task starting to execute and that task

 * calling vTaskDelay () may not be fixed [the task may take a different path though the

 * code between calls, or may get interrupted or preempted a different number of times

 * each time it executes].

 *

 * Whereas vTaskDelay () specifies a wake time relative to the time at which the function

 * is called, vTaskDelayUntil () specifies the absolute (exact) time at which it wishes to

 * unblock.

 *

 * The constant portTICK_RATE_MS can be used to calculate real time from the tick

 * rate - with the resolution of one tick period.

 *

 * @param pxPreviousWakeTime Pointer to a variable that holds the time at which the

 * task was last unblocked.  The variable must be initialised with the current time

 * prior to its first use (see the example below).  Following this the variable is

 * automatically updated within vTaskDelayUntil ().

 *

 * @param xTimeIncrement The cycle time period.  The task will be unblocked at

 * time *pxPreviousWakeTime + xTimeIncrement.  Calling vTaskDelayUntil with the

 * same xTimeIncrement parameter value will cause the task to execute with

 * a fixed interface period.

 *

 * Example usage:

   <pre>

 // Perform an action every 10 ticks.

 void vTaskFunction( void * pvParameters )

 {

 portTickType xLastWakeTime;

 const portTickType xFrequency = 10;

         // Initialise the xLastWakeTime variable with the current time.

         xLastWakeTime = xTaskGetTickCount ();

         for( ;; )

         {

                 // Wait for the next cycle.

                 vTaskDelayUntil( &xLastWakeTime, xFrequency );

                 // Perform action here.

         }

 }

   </pre>

 * \defgroup vTaskDelayUntil vTaskDelayUntil

 * \ingroup TaskCtrl

 */

void vTaskDelayUntil( portTickType * const pxPreviousWakeTime, portTickType xTimeIncrement ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>unsigned portBASE_TYPE uxTaskPriorityGet( xTaskHandle pxTask );</pre>

 *

 * INCLUDE_xTaskPriorityGet must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Obtain the priority of any task.

 *

 * @param pxTask Handle of the task to be queried.  Passing a NULL

 * handle results in the priority of the calling task being returned.

 *

 * @return The priority of pxTask.

 *

 * Example usage:

   <pre>

 void vAFunction( void )

 {

 xTaskHandle xHandle;

         // Create a task, storing the handle.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, &xHandle );

         // ...

         // Use the handle to obtain the priority of the created task.

         // It was created with tskIDLE_PRIORITY, but may have changed

         // it itself.

         if( uxTaskPriorityGet( xHandle ) != tskIDLE_PRIORITY )

         {

                 // The task has changed it's priority.

         }

         // ...

         // Is our priority higher than the created task?

         if( uxTaskPriorityGet( xHandle ) < uxTaskPriorityGet( NULL ) )

         {

                 // Our priority (obtained using NULL handle) is higher.

         }

 }

   </pre>

 * \defgroup uxTaskPriorityGet uxTaskPriorityGet

 * \ingroup TaskCtrl

 */

unsigned portBASE_TYPE uxTaskPriorityGet( xTaskHandle pxTask ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskPrioritySet( xTaskHandle pxTask, unsigned portBASE_TYPE uxNewPriority );</pre>

 *

 * INCLUDE_vTaskPrioritySet must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Set the priority of any task.

 *

 * A context switch will occur before the function returns if the priority

 * being set is higher than the currently executing task.

 *

 * @param pxTask Handle to the task for which the priority is being set.

 * Passing a NULL handle results in the priority of the calling task being set.

 *

 * @param uxNewPriority The priority to which the task will be set.

 *

 * Example usage:

   <pre>

 void vAFunction( void )

 {

 xTaskHandle xHandle;

         // Create a task, storing the handle.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, &xHandle );

         // ...

         // Use the handle to raise the priority of the created task.

         vTaskPrioritySet( xHandle, tskIDLE_PRIORITY + 1 );

         // ...

         // Use a NULL handle to raise our priority to the same value.

         vTaskPrioritySet( NULL, tskIDLE_PRIORITY + 1 );

 }

   </pre>

 * \defgroup vTaskPrioritySet vTaskPrioritySet

 * \ingroup TaskCtrl

 */

void vTaskPrioritySet( xTaskHandle pxTask, unsigned portBASE_TYPE uxNewPriority ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskSuspend( xTaskHandle pxTaskToSuspend );</pre>

 *

 * INCLUDE_vTaskSuspend must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Suspend any task.  When suspended a task will never get any microcontroller

 * processing time, no matter what its priority.

 *

 * Calls to vTaskSuspend are not accumulative -

 * i.e. calling vTaskSuspend () twice on the same task still only requires one

 * call to vTaskResume () to ready the suspended task.

 *

 * @param pxTaskToSuspend Handle to the task being suspended.  Passing a NULL

 * handle will cause the calling task to be suspended.

 *

 * Example usage:

   <pre>

 void vAFunction( void )

 {

 xTaskHandle xHandle;

         // Create a task, storing the handle.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, &xHandle );

         // ...

         // Use the handle to suspend the created task.

         vTaskSuspend( xHandle );

         // ...

         // The created task will not run during this period, unless

         // another task calls vTaskResume( xHandle ).

         //...

         // Suspend ourselves.

         vTaskSuspend( NULL );

         // We cannot get here unless another task calls vTaskResume

         // with our handle as the parameter.

 }

   </pre>

 * \defgroup vTaskSuspend vTaskSuspend

 * \ingroup TaskCtrl

 */

void vTaskSuspend( xTaskHandle pxTaskToSuspend ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskResume( xTaskHandle pxTaskToResume );</pre>

 *

 * INCLUDE_vTaskSuspend must be defined as 1 for this function to be available.

 * See the configuration section for more information.

 *

 * Resumes a suspended task.

 *

 * A task that has been suspended by one of more calls to vTaskSuspend ()

 * will be made available for running again by a single call to

 * vTaskResume ().

 *

 * @param pxTaskToResume Handle to the task being readied.

 *

 * Example usage:

   <pre>

 void vAFunction( void )

 {

 xTaskHandle xHandle;

         // Create a task, storing the handle.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, &xHandle );

         // ...

         // Use the handle to suspend the created task.

         vTaskSuspend( xHandle );

         // ...

         // The created task will not run during this period, unless

         // another task calls vTaskResume( xHandle ).

         //...

         // Resume the suspended task ourselves.

         vTaskResume( xHandle );

         // The created task will once again get microcontroller processing

         // time in accordance with it priority within the system.

 }

   </pre>

 * \defgroup vTaskResume vTaskResume

 * \ingroup TaskCtrl

 */

void vTaskResume( xTaskHandle pxTaskToResume ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void xTaskResumeFromISR( xTaskHandle pxTaskToResume );</pre>

 *

 * INCLUDE_xTaskResumeFromISR must be defined as 1 for this function to be

 * available.  See the configuration section for more information.

 *

 * An implementation of vTaskResume() that can be called from within an ISR.

 *

 * A task that has been suspended by one of more calls to vTaskSuspend ()

 * will be made available for running again by a single call to

 * xTaskResumeFromISR ().

 *

 * @param pxTaskToResume Handle to the task being readied.

 *

 * \defgroup vTaskResumeFromISR vTaskResumeFromISR

 * \ingroup TaskCtrl

 */

portBASE_TYPE xTaskResumeFromISR( xTaskHandle pxTaskToResume ) PRIVILEGED_FUNCTION;

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

 * SCHEDULER CONTROL

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

/**

 * task. h

 * <pre>void vTaskStartScheduler( void );</pre>

 *

 * Starts the real time kernel tick processing.  After calling the kernel

 * has control over which tasks are executed and when.  This function

 * does not return until an executing task calls vTaskEndScheduler ().

 *

 * At least one task should be created via a call to xTaskCreate ()

 * before calling vTaskStartScheduler ().  The idle task is created

 * automatically when the first application task is created.

 *

 * See the demo application file main.c for an example of creating

 * tasks and starting the kernel.

 *

 * Example usage:

   <pre>

 void vAFunction( void )

 {

         // Create at least one task before starting the kernel.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );

         // Start the real time kernel with preemption.

         vTaskStartScheduler ();

         // Will not get here unless a task calls vTaskEndScheduler ()

 }

   </pre>

 *

 * \defgroup vTaskStartScheduler vTaskStartScheduler

 * \ingroup SchedulerControl

 */

void vTaskStartScheduler( void ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskEndScheduler( void );</pre>

 *

 * Stops the real time kernel tick.  All created tasks will be automatically

 * deleted and multitasking (either preemptive or cooperative) will

 * stop.  Execution then resumes from the point where vTaskStartScheduler ()

 * was called, as if vTaskStartScheduler () had just returned.

 *

 * See the demo application file main. c in the demo/PC directory for an

 * example that uses vTaskEndScheduler ().

 *

 * vTaskEndScheduler () requires an exit function to be defined within the

 * portable layer (see vPortEndScheduler () in port. c for the PC port).  This

 * performs hardware specific operations such as stopping the kernel tick.

 *

 * vTaskEndScheduler () will cause all of the resources allocated by the

 * kernel to be freed - but will not free resources allocated by application

 * tasks.

 *

 * Example usage:

   <pre>

 void vTaskCode( void * pvParameters )

 {

         for( ;; )

         {

                 // Task code goes here.

                 // At some point we want to end the real time kernel processing

                 // so call ...

                 vTaskEndScheduler ();

         }

 }

 void vAFunction( void )

 {

         // Create at least one task before starting the kernel.

         xTaskCreate( vTaskCode, "NAME", STACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );

         // Start the real time kernel with preemption.

         vTaskStartScheduler ();

         // Will only get here when the vTaskCode () task has called

         // vTaskEndScheduler ().  When we get here we are back to single task

         // execution.

 }

   </pre>

 *

 * \defgroup vTaskEndScheduler vTaskEndScheduler

 * \ingroup SchedulerControl

 */

void vTaskEndScheduler( void ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>void vTaskSuspendAll( void );</pre>

 *

 * Suspends all real time kernel activity while keeping interrupts (including the

 * kernel tick) enabled.

 *

 * After calling vTaskSuspendAll () the calling task will continue to execute

 * without risk of being swapped out until a call to xTaskResumeAll () has been

 * made.

 *

 * API functions that have the potential to cause a context switch (for example,

 * vTaskDelayUntil(), xQueueSend(), etc.) must not be called while the scheduler

 * is suspended.

 *

 * Example usage:

   <pre>

 void vTask1( void * pvParameters )

 {

         for( ;; )

         {

                 // Task code goes here.

                 // ...

                 // At some point the task wants to perform a long operation during

                 // which it does not want to get swapped out.  It cannot use

                 // taskENTER_CRITICAL ()/taskEXIT_CRITICAL () as the length of the

                 // operation may cause interrupts to be missed - including the

                 // ticks.

                 // Prevent the real time kernel swapping out the task.

                 vTaskSuspendAll ();

                 // Perform the operation here.  There is no need to use critical

                 // sections as we have all the microcontroller processing time.

                 // During this time interrupts will still operate and the kernel

                 // tick count will be maintained.

                 // ...

                 // The operation is complete.  Restart the kernel.

                 xTaskResumeAll ();

         }

 }

   </pre>

 * \defgroup vTaskSuspendAll vTaskSuspendAll

 * \ingroup SchedulerControl

 */

void vTaskSuspendAll( void ) PRIVILEGED_FUNCTION;

/**

 * task. h

 * <pre>char xTaskResumeAll( void );</pre>

 *

 * Resumes real time kernel activity following a call to vTaskSuspendAll ().

 * After a call to vTaskSuspendAll () the kernel will take control of which

 * task is executing at any time.

 *

 * @return If resuming the scheduler caused a context switch then pdTRUE is

 *                returned, otherwise pdFALSE is returned.

 *

 * Example usage:

   <pre>

 void vTask1( void * pvParameters )

 {

         for( ;; )

         {

                 // Task code goes here.