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/* FreeRTOS.org V4.2.0 - Copyright (C) 2003-2007 Richard Barry. This file is part of the FreeRTOS.org distribution. FreeRTOS.org is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. FreeRTOS.org 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 along with FreeRTOS.org; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA A special exception to the GPL can be applied should you wish to distribute a combined work that includes FreeRTOS.org, without being obliged to provide the source code for any proprietary components. See the licensing section of http://www.FreeRTOS.org for full details of how and when the exception can be applied. *************************************************************************** See http://www.FreeRTOS.org for documentation, latest information, license and contact details. Please ensure to read the configuration and relevant port sections of the online documentation. *************************************************************************** */ #ifndef TASK_H #define TASK_H #include "portable.h" #include "list.h" /*----------------------------------------------------------- * MACROS AND DEFINITIONS *----------------------------------------------------------*/ #define tskKERNEL_VERSION_NUMBER "V4.2.0" /** * 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 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() /*----------------------------------------------------------- * TASK CREATION API *----------------------------------------------------------*/ /** * task. h *<pre> portBASE_TYPE xTaskCreate( pdTASK_CODE pvTaskCode, const portCHAR * const pcName, unsigned portSHORT 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. * * @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. * * @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 ) { unsigned char ucParameterToPass; xTaskHandle xHandle; // Create the task, storing the handle. xTaskCreate( vTaskCode, "NAME", STACK_SIZE, &ucParameterToPass, tskIDLE_PRIORITY, &xHandle ); // Use the handle to delete the task. vTaskDelete( xHandle ); } </pre> * \defgroup xTaskCreate xTaskCreate * \ingroup Tasks */ signed portBASE_TYPE xTaskCreate( pdTASK_CODE pvTaskCode, const signed portCHAR * const pcName, unsigned portSHORT usStackDepth, void *pvParameters, unsigned portBASE_TYPE uxPriority, xTaskHandle *pvCreatedTask ); /** * 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 ); /*----------------------------------------------------------- * 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. * * @param xTicksToDelay The amount of time, in tick periods, that * the calling task should block. * * Example usage: <pre> // Wait 10 ticks before performing an action. // NOTE: // This is for demonstration only and would be better achieved // using vTaskDelayUntil (). void vTaskFunction( void * pvParameters ) { portTickType xDelay, xNextTime; // Calc the time at which we want to perform the action // next. xNextTime = xTaskGetTickCount () + ( portTickType ) 10; for( ;; ) { xDelay = xNextTime - xTaskGetTickCount (); xNextTime += ( portTickType ) 10; // Guard against overflow if( xDelay <= ( portTickType ) 10 ) { vTaskDelay( xDelay ); } // Perform action here. } } </pre> * \defgroup vTaskDelay vTaskDelay * \ingroup TaskCtrl */ void vTaskDelay( portTickType xTicksToDelay ); /** * 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 *pxPreviousWakeTime, portTickType xTimeIncrement ); /** * 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 ); /** * 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 ); /** * 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 ); /** * 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 ); /** * 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 ); /*----------------------------------------------------------- * 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 ); /** * 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 ); /** * 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. * * 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 ); /** * task. h * <pre>portCHAR 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. // ... // 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 real // time kernel tick count will be maintained. // ... // The operation is complete. Restart the kernel. We want to force // a context switch - but there is no point if resuming the scheduler // caused a context switch already. if( !xTaskResumeAll () ) { taskYIELD (); } } } </pre> * \defgroup xTaskResumeAll xTaskResumeAll * \ingroup SchedulerControl */ signed portBASE_TYPE xTaskResumeAll( void ); /*----------------------------------------------------------- * TASK UTILITIES *----------------------------------------------------------*/ /** * task. h * <PRE>volatile portTickType xTaskGetTickCount( void );</PRE> * * @return The count of ticks since vTaskStartScheduler was called. * * \page xTaskGetTickCount xTaskGetTickCount * \ingroup TaskUtils */ portTickType xTaskGetTickCount( void ); /** * task. h * <PRE>unsigned portSHORT uxTaskGetNumberOfTasks( void );</PRE> * * @return The number of tasks that the real time kernel is currently managing. * This includes all ready, blocked and suspended tasks. A task that * has been deleted but not yet freed by the idle task will also be * included in the count. * * \page uxTaskGetNumberOfTasks uxTaskGetNumberOfTasks * \ingroup TaskUtils */ unsigned portBASE_TYPE uxTaskGetNumberOfTasks( void ); /** * task. h * <PRE>void vTaskList( portCHAR *pcWriteBuffer );</PRE> * * configUSE_TRACE_FACILITY, INCLUDE_vTaskDelete and INCLUDE_vTaskSuspend * must all be defined as 1 for this function to be available. * See the configuration section for more information. * * NOTE: This function will disable interrupts for its duration. It is * not intended for normal application runtime use but as a debug aid. * * Lists all the current tasks, along with their current state and stack * usage high water mark. * * Tasks are reported as blocked ('B'), ready ('R'), deleted ('D') or * suspended ('S'). * * @param pcWriteBuffer A buffer into which the above mentioned details * will be written, in ascii form. This buffer is assumed to be large * enough to contain the generated report. Approximately 40 bytes per * task should be sufficient. * * \page vTaskList vTaskList * \ingroup TaskUtils */ void vTaskList( signed portCHAR *pcWriteBuffer ); /** * task. h * <PRE>void vTaskStartTrace( portCHAR * pcBuffer, unsigned portBASE_TYPE uxBufferSize );</PRE> * * Starts a real time kernel activity trace. The trace logs the identity of * which task is running when. * * The trace file is stored in binary format. A separate DOS utility called * convtrce.exe is used to convert this into a tab delimited text file which * can be viewed and plotted in a spread sheet. * * @param pcBuffer The buffer into which the trace will be written. * * @param ulBufferSize The size of pcBuffer in bytes. The trace will continue * until either the buffer in full, or ulTaskEndTrace () is called. * * \page vTaskStartTrace vTaskStartTrace * \ingroup TaskUtils */ void vTaskStartTrace( signed portCHAR * pcBuffer, unsigned portLONG ulBufferSize ); /** * task. h * <PRE>unsigned portLONG ulTaskEndTrace( void );</PRE> * * Stops a kernel activity trace. See vTaskStartTrace (). * * @return The number of bytes that have been written into the trace buffer. * * \page usTaskEndTrace usTaskEndTrace * \ingroup TaskUtils */ unsigned portLONG ulTaskEndTrace( void ); /*----------------------------------------------------------- * SCHEDULER INTERNALS AVAILABLE FOR PORTING PURPOSES *----------------------------------------------------------*/ /* * THIS FUNCTION MUST NOT BE USED FROM APPLICATION CODE. IT IS ONLY * INTENDED FOR USE WHEN IMPLEMENTING A PORT OF THE SCHEDULER AND IS * AN INTERFACE WHICH IS FOR THE EXCLUSIVE USE OF THE SCHEDULER. * * Called from the real time kernel tick (either preemptive or cooperative), * this increments the tick count and checks if any tasks that are blocked * for a finite period required removing from a blocked list and placing on * a ready list. */ inline void vTaskIncrementTick( void ); /* * THIS FUNCTION MUST NOT BE USED FROM APPLICATION CODE. IT IS AN * INTERFACE WHICH IS FOR THE EXCLUSIVE USE OF THE SCHEDULER. * * THIS FUNCTION MUST BE CALLED WITH INTERRUPTS DISABLED. * * Removes the calling task from the ready list and places it both * on the list of tasks waiting for a particular event, and the * list of delayed tasks. The task will be removed from both lists * and replaced on the ready list should either the event occur (and * there be no higher priority tasks waiting on the same event) or * the delay period expires. * * @param pxEventList The list containing tasks that are blocked waiting * for the event to occur. * * @param xTicksToWait The maximum amount of time that the task should wait * for the event to occur. This is specified in kernel ticks,the constant * portTICK_RATE_MS can be used to convert kernel ticks into a real time * period. */ void vTaskPlaceOnEventList( xList *pxEventList, portTickType xTicksToWait ); /* * THIS FUNCTION MUST NOT BE USED FROM APPLICATION CODE. IT IS AN * INTERFACE WHICH IS FOR THE EXCLUSIVE USE OF THE SCHEDULER. * * THIS FUNCTION MUST BE CALLED WITH INTERRUPTS DISABLED. * * Removes a task from both the specified event list and the list of blocked * tasks, and places it on a ready queue. * * xTaskRemoveFromEventList () will be called if either an event occurs to * unblock a task, or the block timeout period expires. * * @return pdTRUE if the task being removed has a higher priority than the task * making the call, otherwise pdFALSE. */ signed portBASE_TYPE xTaskRemoveFromEventList( const xList *pxEventList ); /* * THIS FUNCTION MUST NOT BE USED FROM APPLICATION CODE. IT IS AN * INTERFACE WHICH IS FOR THE EXCLUSIVE USE OF THE SCHEDULER. * * INCLUDE_vTaskCleanUpResources and INCLUDE_vTaskSuspend must be defined as 1 * for this function to be available. * See the configuration section for more information. * * Empties the ready and delayed queues of task control blocks, freeing the * memory allocated for the task control block and task stacks as it goes. */ void vTaskCleanUpResources( void ); /* * THIS FUNCTION MUST NOT BE USED FROM APPLICATION CODE. IT IS ONLY * INTENDED FOR USE WHEN IMPLEMENTING A PORT OF THE SCHEDULER AND IS * AN INTERFACE WHICH IS FOR THE EXCLUSIVE USE OF THE SCHEDULER. * * Sets the pointer to the current TCB to the TCB of the highest priority task * that is ready to run. */ inline void vTaskSwitchContext( void ); /* * Return the handle of the calling task. */ xTaskHandle xTaskGetCurrentTaskHandle( void ); /* * Capture the current time status for future reference. */ void vTaskSetTimeOutState( xTimeOutType *pxTimeOut ); /* * Compare the time status now with that previously captured to see if the * timeout has expired. */ portBASE_TYPE xTaskCheckForTimeOut( xTimeOutType *pxTimeOut, portTickType *pxTicksToWait ); /* * Shortcut used by the queue implementation to prevent unnecessary call to * taskYIELD(); */ void vTaskMissedYield( void ); #endif /* TASK_H */