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Add uncrustify github workflow (#659)

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* Add uncrustify github workflow

* Fix exclusion pattern

* fix find expression

* exclude uncrustify files

* Uncrustify common demo and test files

* exlude white space checking files

* Fix EOL whitespace checker

* Remove whitespaces from EOL

* Fix space at EOL

* Fix find spaces at EOL

Co-authored-by: Archit Aggarwal <architag@amazon.com>
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386
FreeRTOS/Demo/Common/Full/BlockQ.c
View file

@ -28,23 +28,23 @@
/**
* Creates six tasks that operate on three queues as follows:
*
* The first two tasks send and receive an incrementing number to/from a queue.
* One task acts as a producer and the other as the consumer. The consumer is a
* higher priority than the producer and is set to block on queue reads. The queue
* only has space for one item - as soon as the producer posts a message on the
* The first two tasks send and receive an incrementing number to/from a queue.
* One task acts as a producer and the other as the consumer. The consumer is a
* higher priority than the producer and is set to block on queue reads. The queue
* only has space for one item - as soon as the producer posts a message on the
* queue the consumer will unblock, pre-empt the producer, and remove the item.
*
*
* The second two tasks work the other way around. Again the queue used only has
* enough space for one item. This time the consumer has a lower priority than the
* producer. The producer will try to post on the queue blocking when the queue is
* full. When the consumer wakes it will remove the item from the queue, causing
* the producer to unblock, pre-empt the consumer, and immediately re-fill the
* enough space for one item. This time the consumer has a lower priority than the
* producer. The producer will try to post on the queue blocking when the queue is
* full. When the consumer wakes it will remove the item from the queue, causing
* the producer to unblock, pre-empt the consumer, and immediately re-fill the
* queue.
*
*
* The last two tasks use the same queue producer and consumer functions. This time the queue has
* enough space for lots of items and the tasks operate at the same priority. The
* producer will execute, placing items into the queue. The consumer will start
* executing when either the queue becomes full (causing the producer to block) or
* enough space for lots of items and the tasks operate at the same priority. The
* producer will execute, placing items into the queue. The consumer will start
* executing when either the queue becomes full (causing the producer to block) or
* a context switch occurs (tasks of the same priority will time slice).
*
* \page BlockQC blockQ.c
@ -53,21 +53,21 @@
*/
/*
Changes from V1.00:
+ Reversed the priority and block times of the second two demo tasks so
they operate as per the description above.
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
Changes from V4.0.2
+ The second set of tasks were created the wrong way around. This has been
corrected.
*/
* Changes from V1.00:
*
+ Reversed the priority and block times of the second two demo tasks so
+ they operate as per the description above.
+
+ Changes from V2.0.0
+
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
+
+ Changes from V4.0.2
+
+ The second set of tasks were created the wrong way around. This has been
+ corrected.
*/
#include <stdlib.h>
@ -81,228 +81,228 @@ Changes from V4.0.2
#include "BlockQ.h"
#include "print.h"
#define blckqSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
#define blckqNUM_TASK_SETS ( 3 )
#define blckqSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
#define blckqNUM_TASK_SETS ( 3 )
/* Structure used to pass parameters to the blocking queue tasks. */
typedef struct BLOCKING_QUEUE_PARAMETERS
{
QueueHandle_t xQueue; /*< The queue to be used by the task. */
TickType_t xBlockTime; /*< The block time to use on queue reads/writes. */
volatile short *psCheckVariable; /*< Incremented on each successful cycle to check the task is still running. */
QueueHandle_t xQueue; /*< The queue to be used by the task. */
TickType_t xBlockTime; /*< The block time to use on queue reads/writes. */
volatile short * psCheckVariable; /*< Incremented on each successful cycle to check the task is still running. */
} xBlockingQueueParameters;
/* Task function that creates an incrementing number and posts it on a queue. */
static void vBlockingQueueProducer( void *pvParameters );
static void vBlockingQueueProducer( void * pvParameters );
/* Task function that removes the incrementing number from a queue and checks that
it is the expected number. */
static void vBlockingQueueConsumer( void *pvParameters );
/* Task function that removes the incrementing number from a queue and checks that
* it is the expected number. */
static void vBlockingQueueConsumer( void * pvParameters );
/* Variables which are incremented each time an item is removed from a queue, and
found to be the expected value.
These are used to check that the tasks are still running. */
/* Variables which are incremented each time an item is removed from a queue, and
* found to be the expected value.
* These are used to check that the tasks are still running. */
static volatile short sBlockingConsumerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
/* Variable which are incremented each time an item is posted on a queue. These
are used to check that the tasks are still running. */
/* Variable which are incremented each time an item is posted on a queue. These
* are used to check that the tasks are still running. */
static volatile short sBlockingProducerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
/*-----------------------------------------------------------*/
void vStartBlockingQueueTasks( unsigned portBASE_TYPE uxPriority )
{
xBlockingQueueParameters *pxQueueParameters1, *pxQueueParameters2;
xBlockingQueueParameters *pxQueueParameters3, *pxQueueParameters4;
xBlockingQueueParameters *pxQueueParameters5, *pxQueueParameters6;
const unsigned portBASE_TYPE uxQueueSize1 = 1, uxQueueSize5 = 5;
const TickType_t xBlockTime = ( TickType_t ) 1000 / portTICK_PERIOD_MS;
const TickType_t xDontBlock = ( TickType_t ) 0;
xBlockingQueueParameters * pxQueueParameters1, * pxQueueParameters2;
xBlockingQueueParameters * pxQueueParameters3, * pxQueueParameters4;
xBlockingQueueParameters * pxQueueParameters5, * pxQueueParameters6;
const unsigned portBASE_TYPE uxQueueSize1 = 1, uxQueueSize5 = 5;
const TickType_t xBlockTime = ( TickType_t ) 1000 / portTICK_PERIOD_MS;
const TickType_t xDontBlock = ( TickType_t ) 0;
/* Create the first two tasks as described at the top of the file. */
/* First create the structure used to pass parameters to the consumer tasks. */
pxQueueParameters1 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
/* Create the first two tasks as described at the top of the file. */
/* Create the queue used by the first two tasks to pass the incrementing number.
Pass a pointer to the queue in the parameter structure. */
pxQueueParameters1->xQueue = xQueueCreate( uxQueueSize1, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
/* First create the structure used to pass parameters to the consumer tasks. */
pxQueueParameters1 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
/* The consumer is created first so gets a block time as described above. */
pxQueueParameters1->xBlockTime = xBlockTime;
/* Create the queue used by the first two tasks to pass the incrementing number.
* Pass a pointer to the queue in the parameter structure. */
pxQueueParameters1->xQueue = xQueueCreate( uxQueueSize1, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
/* Pass in the variable that this task is going to increment so we can check it
is still running. */
pxQueueParameters1->psCheckVariable = &( sBlockingConsumerCount[ 0 ] );
/* Create the structure used to pass parameters to the producer task. */
pxQueueParameters2 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
/* The consumer is created first so gets a block time as described above. */
pxQueueParameters1->xBlockTime = xBlockTime;
/* Pass the queue to this task also, using the parameter structure. */
pxQueueParameters2->xQueue = pxQueueParameters1->xQueue;
/* Pass in the variable that this task is going to increment so we can check it
* is still running. */
pxQueueParameters1->psCheckVariable = &( sBlockingConsumerCount[ 0 ] );
/* The producer is not going to block - as soon as it posts the consumer will
wake and remove the item so the producer should always have room to post. */
pxQueueParameters2->xBlockTime = xDontBlock;
/* Create the structure used to pass parameters to the producer task. */
pxQueueParameters2 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
/* Pass in the variable that this task is going to increment so we can check
it is still running. */
pxQueueParameters2->psCheckVariable = &( sBlockingProducerCount[ 0 ] );
/* Pass the queue to this task also, using the parameter structure. */
pxQueueParameters2->xQueue = pxQueueParameters1->xQueue;
/* The producer is not going to block - as soon as it posts the consumer will
* wake and remove the item so the producer should always have room to post. */
pxQueueParameters2->xBlockTime = xDontBlock;
/* Pass in the variable that this task is going to increment so we can check
* it is still running. */
pxQueueParameters2->psCheckVariable = &( sBlockingProducerCount[ 0 ] );
/* Note the producer has a lower priority than the consumer when the tasks are
spawned. */
xTaskCreate( vBlockingQueueConsumer, "QConsB1", blckqSTACK_SIZE, ( void * ) pxQueueParameters1, uxPriority, NULL );
xTaskCreate( vBlockingQueueProducer, "QProdB2", blckqSTACK_SIZE, ( void * ) pxQueueParameters2, tskIDLE_PRIORITY, NULL );
/* Create the second two tasks as described at the top of the file. This uses
the same mechanism but reverses the task priorities. */
pxQueueParameters3 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters3->xQueue = xQueueCreate( uxQueueSize1, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
pxQueueParameters3->xBlockTime = xDontBlock;
pxQueueParameters3->psCheckVariable = &( sBlockingProducerCount[ 1 ] );
pxQueueParameters4 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters4->xQueue = pxQueueParameters3->xQueue;
pxQueueParameters4->xBlockTime = xBlockTime;
pxQueueParameters4->psCheckVariable = &( sBlockingConsumerCount[ 1 ] );
xTaskCreate( vBlockingQueueProducer, "QProdB3", blckqSTACK_SIZE, ( void * ) pxQueueParameters3, tskIDLE_PRIORITY, NULL );
xTaskCreate( vBlockingQueueConsumer, "QConsB4", blckqSTACK_SIZE, ( void * ) pxQueueParameters4, uxPriority, NULL );
/* Note the producer has a lower priority than the consumer when the tasks are
* spawned. */
xTaskCreate( vBlockingQueueConsumer, "QConsB1", blckqSTACK_SIZE, ( void * ) pxQueueParameters1, uxPriority, NULL );
xTaskCreate( vBlockingQueueProducer, "QProdB2", blckqSTACK_SIZE, ( void * ) pxQueueParameters2, tskIDLE_PRIORITY, NULL );
/* Create the last two tasks as described above. The mechanism is again just
the same. This time both parameter structures are given a block time. */
pxQueueParameters5 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters5->xQueue = xQueueCreate( uxQueueSize5, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
pxQueueParameters5->xBlockTime = xBlockTime;
pxQueueParameters5->psCheckVariable = &( sBlockingProducerCount[ 2 ] );
/* Create the second two tasks as described at the top of the file. This uses
* the same mechanism but reverses the task priorities. */
pxQueueParameters6 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters6->xQueue = pxQueueParameters5->xQueue;
pxQueueParameters6->xBlockTime = xBlockTime;
pxQueueParameters6->psCheckVariable = &( sBlockingConsumerCount[ 2 ] );
pxQueueParameters3 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters3->xQueue = xQueueCreate( uxQueueSize1, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
pxQueueParameters3->xBlockTime = xDontBlock;
pxQueueParameters3->psCheckVariable = &( sBlockingProducerCount[ 1 ] );
xTaskCreate( vBlockingQueueProducer, "QProdB5", blckqSTACK_SIZE, ( void * ) pxQueueParameters5, tskIDLE_PRIORITY, NULL );
xTaskCreate( vBlockingQueueConsumer, "QConsB6", blckqSTACK_SIZE, ( void * ) pxQueueParameters6, tskIDLE_PRIORITY, NULL );
pxQueueParameters4 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters4->xQueue = pxQueueParameters3->xQueue;
pxQueueParameters4->xBlockTime = xBlockTime;
pxQueueParameters4->psCheckVariable = &( sBlockingConsumerCount[ 1 ] );
xTaskCreate( vBlockingQueueProducer, "QProdB3", blckqSTACK_SIZE, ( void * ) pxQueueParameters3, tskIDLE_PRIORITY, NULL );
xTaskCreate( vBlockingQueueConsumer, "QConsB4", blckqSTACK_SIZE, ( void * ) pxQueueParameters4, uxPriority, NULL );
/* Create the last two tasks as described above. The mechanism is again just
* the same. This time both parameter structures are given a block time. */
pxQueueParameters5 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters5->xQueue = xQueueCreate( uxQueueSize5, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
pxQueueParameters5->xBlockTime = xBlockTime;
pxQueueParameters5->psCheckVariable = &( sBlockingProducerCount[ 2 ] );
pxQueueParameters6 = ( xBlockingQueueParameters * ) pvPortMalloc( sizeof( xBlockingQueueParameters ) );
pxQueueParameters6->xQueue = pxQueueParameters5->xQueue;
pxQueueParameters6->xBlockTime = xBlockTime;
pxQueueParameters6->psCheckVariable = &( sBlockingConsumerCount[ 2 ] );
xTaskCreate( vBlockingQueueProducer, "QProdB5", blckqSTACK_SIZE, ( void * ) pxQueueParameters5, tskIDLE_PRIORITY, NULL );
xTaskCreate( vBlockingQueueConsumer, "QConsB6", blckqSTACK_SIZE, ( void * ) pxQueueParameters6, tskIDLE_PRIORITY, NULL );
}
/*-----------------------------------------------------------*/
static void vBlockingQueueProducer( void *pvParameters )
static void vBlockingQueueProducer( void * pvParameters )
{
unsigned short usValue = 0;
xBlockingQueueParameters *pxQueueParameters;
const char * const pcTaskStartMsg = "Blocking queue producer started.\r\n";
const char * const pcTaskErrorMsg = "Could not post on blocking queue\r\n";
short sErrorEverOccurred = pdFALSE;
unsigned short usValue = 0;
xBlockingQueueParameters * pxQueueParameters;
const char * const pcTaskStartMsg = "Blocking queue producer started.\r\n";
const char * const pcTaskErrorMsg = "Could not post on blocking queue\r\n";
short sErrorEverOccurred = pdFALSE;
pxQueueParameters = ( xBlockingQueueParameters * ) pvParameters;
pxQueueParameters = ( xBlockingQueueParameters * ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
if( xQueueSendToBack( pxQueueParameters->xQueue, ( void * ) &usValue, pxQueueParameters->xBlockTime ) != pdPASS )
{
vPrintDisplayMessage( &pcTaskErrorMsg );
sErrorEverOccurred = pdTRUE;
}
else
{
/* We have successfully posted a message, so increment the variable
used to check we are still running. */
if( sErrorEverOccurred == pdFALSE )
{
( *pxQueueParameters->psCheckVariable )++;
}
for( ; ; )
{
if( xQueueSendToBack( pxQueueParameters->xQueue, ( void * ) &usValue, pxQueueParameters->xBlockTime ) != pdPASS )
{
vPrintDisplayMessage( &pcTaskErrorMsg );
sErrorEverOccurred = pdTRUE;
}
else
{
/* We have successfully posted a message, so increment the variable
* used to check we are still running. */
if( sErrorEverOccurred == pdFALSE )
{
( *pxQueueParameters->psCheckVariable )++;
}
/* Increment the variable we are going to post next time round. The
consumer will expect the numbers to follow in numerical order. */
++usValue;
}
}
/* Increment the variable we are going to post next time round. The
* consumer will expect the numbers to follow in numerical order. */
++usValue;
}
}
}
/*-----------------------------------------------------------*/
static void vBlockingQueueConsumer( void *pvParameters )
static void vBlockingQueueConsumer( void * pvParameters )
{
unsigned short usData, usExpectedValue = 0;
xBlockingQueueParameters *pxQueueParameters;
const char * const pcTaskStartMsg = "Blocking queue consumer started.\r\n";
const char * const pcTaskErrorMsg = "Incorrect value received on blocking queue.\r\n";
short sErrorEverOccurred = pdFALSE;
unsigned short usData, usExpectedValue = 0;
xBlockingQueueParameters * pxQueueParameters;
const char * const pcTaskStartMsg = "Blocking queue consumer started.\r\n";
const char * const pcTaskErrorMsg = "Incorrect value received on blocking queue.\r\n";
short sErrorEverOccurred = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
pxQueueParameters = ( xBlockingQueueParameters * ) pvParameters;
pxQueueParameters = ( xBlockingQueueParameters * ) pvParameters;
for( ;; )
{
if( xQueueReceive( pxQueueParameters->xQueue, &usData, pxQueueParameters->xBlockTime ) == pdPASS )
{
if( usData != usExpectedValue )
{
vPrintDisplayMessage( &pcTaskErrorMsg );
for( ; ; )
{
if( xQueueReceive( pxQueueParameters->xQueue, &usData, pxQueueParameters->xBlockTime ) == pdPASS )
{
if( usData != usExpectedValue )
{
vPrintDisplayMessage( &pcTaskErrorMsg );
/* Catch-up. */
usExpectedValue = usData;
/* Catch-up. */
usExpectedValue = usData;
sErrorEverOccurred = pdTRUE;
}
else
{
/* We have successfully received a message, so increment the
variable used to check we are still running. */
if( sErrorEverOccurred == pdFALSE )
{
( *pxQueueParameters->psCheckVariable )++;
}
/* Increment the value we expect to remove from the queue next time
round. */
++usExpectedValue;
}
}
}
sErrorEverOccurred = pdTRUE;
}
else
{
/* We have successfully received a message, so increment the
* variable used to check we are still running. */
if( sErrorEverOccurred == pdFALSE )
{
( *pxQueueParameters->psCheckVariable )++;
}
/* Increment the value we expect to remove from the queue next time
* round. */
++usExpectedValue;
}
}
}
}
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running. */
portBASE_TYPE xAreBlockingQueuesStillRunning( void )
{
static short sLastBlockingConsumerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
static short sLastBlockingProducerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
portBASE_TYPE xReturn = pdPASS, xTasks;
static short sLastBlockingConsumerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
static short sLastBlockingProducerCount[ blckqNUM_TASK_SETS ] = { ( short ) 0, ( short ) 0, ( short ) 0 };
portBASE_TYPE xReturn = pdPASS, xTasks;
/* Not too worried about mutual exclusion on these variables as they are 16
bits and we are only reading them. We also only care to see if they have
changed or not.
Loop through each check variable and return pdFALSE if any are found not
to have changed since the last call. */
/* Not too worried about mutual exclusion on these variables as they are 16
* bits and we are only reading them. We also only care to see if they have
* changed or not.
*
* Loop through each check variable and return pdFALSE if any are found not
* to have changed since the last call. */
for( xTasks = 0; xTasks < blckqNUM_TASK_SETS; xTasks++ )
{
if( sBlockingConsumerCount[ xTasks ] == sLastBlockingConsumerCount[ xTasks ] )
{
xReturn = pdFALSE;
}
sLastBlockingConsumerCount[ xTasks ] = sBlockingConsumerCount[ xTasks ];
for( xTasks = 0; xTasks < blckqNUM_TASK_SETS; xTasks++ )
{
if( sBlockingConsumerCount[ xTasks ] == sLastBlockingConsumerCount[ xTasks ] )
{
xReturn = pdFALSE;
}
sLastBlockingConsumerCount[ xTasks ] = sBlockingConsumerCount[ xTasks ];
if( sBlockingProducerCount[ xTasks ] == sLastBlockingProducerCount[ xTasks ] )
{
xReturn = pdFALSE;
}
sLastBlockingProducerCount[ xTasks ] = sBlockingProducerCount[ xTasks ];
}
if( sBlockingProducerCount[ xTasks ] == sLastBlockingProducerCount[ xTasks ] )
{
xReturn = pdFALSE;
}
return xReturn;
sLastBlockingProducerCount[ xTasks ] = sBlockingProducerCount[ xTasks ];
}
return xReturn;
}

248
FreeRTOS/Demo/Common/Full/PollQ.c
View file

@ -27,24 +27,24 @@
/**
* This is a very simple queue test. See the BlockQ. c documentation for a more
* This is a very simple queue test. See the BlockQ. c documentation for a more
* comprehensive version.
*
* Creates two tasks that communicate over a single queue. One task acts as a
* producer, the other a consumer.
* Creates two tasks that communicate over a single queue. One task acts as a
* producer, the other a consumer.
*
* The producer loops for three iteration, posting an incrementing number onto the
* queue each cycle. It then delays for a fixed period before doing exactly the
* The producer loops for three iteration, posting an incrementing number onto the
* queue each cycle. It then delays for a fixed period before doing exactly the
* same again.
*
* The consumer loops emptying the queue. Each item removed from the queue is
* checked to ensure it contains the expected value. When the queue is empty it
* The consumer loops emptying the queue. Each item removed from the queue is
* checked to ensure it contains the expected value. When the queue is empty it
* blocks for a fixed period, then does the same again.
*
* All queue access is performed without blocking. The consumer completely empties
* the queue each time it runs so the producer should never find the queue full.
* All queue access is performed without blocking. The consumer completely empties
* the queue each time it runs so the producer should never find the queue full.
*
* An error is flagged if the consumer obtains an unexpected value or the producer
* An error is flagged if the consumer obtains an unexpected value or the producer
* find the queue is full.
*
* \page PollQC pollQ.c
@ -53,11 +53,11 @@
*/
/*
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
*/
* Changes from V2.0.0
*
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
*/
#include <stdlib.h>
@ -70,13 +70,13 @@ Changes from V2.0.0
/* Demo program include files. */
#include "PollQ.h"
#define pollqSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
#define pollqSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
/* The task that posts the incrementing number onto the queue. */
static void vPolledQueueProducer( void *pvParameters );
static void vPolledQueueProducer( void * pvParameters );
/* The task that empties the queue. */
static void vPolledQueueConsumer( void *pvParameters );
static void vPolledQueueConsumer( void * pvParameters );
/* Variables that are used to check that the tasks are still running with no errors. */
static volatile short sPollingConsumerCount = 0, sPollingProducerCount = 0;
@ -84,137 +84,139 @@ static volatile short sPollingConsumerCount = 0, sPollingProducerCount = 0;
void vStartPolledQueueTasks( unsigned portBASE_TYPE uxPriority )
{
static QueueHandle_t xPolledQueue;
const unsigned portBASE_TYPE uxQueueSize = 10;
static QueueHandle_t xPolledQueue;
const unsigned portBASE_TYPE uxQueueSize = 10;
/* Create the queue used by the producer and consumer. */
xPolledQueue = xQueueCreate( uxQueueSize, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
/* Create the queue used by the producer and consumer. */
xPolledQueue = xQueueCreate( uxQueueSize, ( unsigned portBASE_TYPE ) sizeof( unsigned short ) );
/* Spawn the producer and consumer. */
xTaskCreate( vPolledQueueConsumer, "QConsNB", pollqSTACK_SIZE, ( void * ) &xPolledQueue, uxPriority, NULL );
xTaskCreate( vPolledQueueProducer, "QProdNB", pollqSTACK_SIZE, ( void * ) &xPolledQueue, uxPriority, NULL );
/* Spawn the producer and consumer. */
xTaskCreate( vPolledQueueConsumer, "QConsNB", pollqSTACK_SIZE, ( void * ) &xPolledQueue, uxPriority, NULL );
xTaskCreate( vPolledQueueProducer, "QProdNB", pollqSTACK_SIZE, ( void * ) &xPolledQueue, uxPriority, NULL );
}
/*-----------------------------------------------------------*/
static void vPolledQueueProducer( void *pvParameters )
static void vPolledQueueProducer( void * pvParameters )
{
unsigned short usValue = 0, usLoop;
QueueHandle_t *pxQueue;
const TickType_t xDelay = ( TickType_t ) 200 / portTICK_PERIOD_MS;
const unsigned short usNumToProduce = 3;
const char * const pcTaskStartMsg = "Polled queue producer started.\r\n";
const char * const pcTaskErrorMsg = "Could not post on polled queue.\r\n";
short sError = pdFALSE;
unsigned short usValue = 0, usLoop;
QueueHandle_t * pxQueue;
const TickType_t xDelay = ( TickType_t ) 200 / portTICK_PERIOD_MS;
const unsigned short usNumToProduce = 3;
const char * const pcTaskStartMsg = "Polled queue producer started.\r\n";
const char * const pcTaskErrorMsg = "Could not post on polled queue.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The queue being used is passed in as the parameter. */
pxQueue = ( QueueHandle_t * ) pvParameters;
/* The queue being used is passed in as the parameter. */
pxQueue = ( QueueHandle_t * ) pvParameters;
for( ;; )
{
for( usLoop = 0; usLoop < usNumToProduce; ++usLoop )
{
/* Send an incrementing number on the queue without blocking. */
if( xQueueSendToBack( *pxQueue, ( void * ) &usValue, ( TickType_t ) 0 ) != pdPASS )
{
/* We should never find the queue full - this is an error. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sError = pdTRUE;
}
else
{
if( sError == pdFALSE )
{
/* If an error has ever been recorded we stop incrementing the
check variable. */
++sPollingProducerCount;
}
for( ; ; )
{
for( usLoop = 0; usLoop < usNumToProduce; ++usLoop )
{
/* Send an incrementing number on the queue without blocking. */
if( xQueueSendToBack( *pxQueue, ( void * ) &usValue, ( TickType_t ) 0 ) != pdPASS )
{
/* We should never find the queue full - this is an error. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sError = pdTRUE;
}
else
{
if( sError == pdFALSE )
{
/* If an error has ever been recorded we stop incrementing the
* check variable. */
++sPollingProducerCount;
}
/* Update the value we are going to post next time around. */
++usValue;
}
}
/* Update the value we are going to post next time around. */
++usValue;
}
}
/* Wait before we start posting again to ensure the consumer runs and
empties the queue. */
vTaskDelay( xDelay );
}
/* Wait before we start posting again to ensure the consumer runs and
* empties the queue. */
vTaskDelay( xDelay );
}
}
/*-----------------------------------------------------------*/
static void vPolledQueueConsumer( void *pvParameters )
static void vPolledQueueConsumer( void * pvParameters )
{
unsigned short usData, usExpectedValue = 0;
QueueHandle_t *pxQueue;
const TickType_t xDelay = ( TickType_t ) 200 / portTICK_PERIOD_MS;
const char * const pcTaskStartMsg = "Polled queue consumer started.\r\n";
const char * const pcTaskErrorMsg = "Incorrect value received on polled queue.\r\n";
short sError = pdFALSE;
unsigned short usData, usExpectedValue = 0;
QueueHandle_t * pxQueue;
const TickType_t xDelay = ( TickType_t ) 200 / portTICK_PERIOD_MS;
const char * const pcTaskStartMsg = "Polled queue consumer started.\r\n";
const char * const pcTaskErrorMsg = "Incorrect value received on polled queue.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The queue being used is passed in as the parameter. */
pxQueue = ( QueueHandle_t * ) pvParameters;
/* The queue being used is passed in as the parameter. */
pxQueue = ( QueueHandle_t * ) pvParameters;
for( ;; )
{
/* Loop until the queue is empty. */
while( uxQueueMessagesWaiting( *pxQueue ) )
{
if( xQueueReceive( *pxQueue, &usData, ( TickType_t ) 0 ) == pdPASS )
{
if( usData != usExpectedValue )
{
/* This is not what we expected to receive so an error has
occurred. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sError = pdTRUE;
/* Catch-up to the value we received so our next expected value
should again be correct. */
usExpectedValue = usData;
}
else
{
if( sError == pdFALSE )
{
/* Only increment the check variable if no errors have
occurred. */
++sPollingConsumerCount;
}
}
++usExpectedValue;
}
}
for( ; ; )
{
/* Loop until the queue is empty. */
while( uxQueueMessagesWaiting( *pxQueue ) )
{
if( xQueueReceive( *pxQueue, &usData, ( TickType_t ) 0 ) == pdPASS )
{
if( usData != usExpectedValue )
{
/* This is not what we expected to receive so an error has
* occurred. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sError = pdTRUE;
/* Now the queue is empty we block, allowing the producer to place more
items in the queue. */
vTaskDelay( xDelay );
}
/* Catch-up to the value we received so our next expected value
* should again be correct. */
usExpectedValue = usData;
}
else
{
if( sError == pdFALSE )
{
/* Only increment the check variable if no errors have
* occurred. */
++sPollingConsumerCount;
}
}
++usExpectedValue;
}
}
/* Now the queue is empty we block, allowing the producer to place more
* items in the queue. */
vTaskDelay( xDelay );
}
}
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running with no errors. */
portBASE_TYPE xArePollingQueuesStillRunning( void )
{
static short sLastPollingConsumerCount = 0, sLastPollingProducerCount = 0;
portBASE_TYPE xReturn;
static short sLastPollingConsumerCount = 0, sLastPollingProducerCount = 0;
portBASE_TYPE xReturn;
if( ( sLastPollingConsumerCount == sPollingConsumerCount ) ||
( sLastPollingProducerCount == sPollingProducerCount )
)
{
xReturn = pdFALSE;
}
else
{
xReturn = pdTRUE;
}
if( ( sLastPollingConsumerCount == sPollingConsumerCount ) ||
( sLastPollingProducerCount == sPollingProducerCount )
)
{
xReturn = pdFALSE;
}
else
{
xReturn = pdTRUE;
}
sLastPollingConsumerCount = sPollingConsumerCount;
sLastPollingProducerCount = sPollingProducerCount;
sLastPollingConsumerCount = sPollingConsumerCount;
sLastPollingProducerCount = sPollingProducerCount;
return xReturn;
return xReturn;
}

443
FreeRTOS/Demo/Common/Full/comtest.c
View file

@ -19,72 +19,72 @@
* IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* https://www.FreeRTOS.org
* https://github.com/FreeRTOS
* https://www.FreeRTOS.org
* https://github.com/FreeRTOS
*
*/
/**
* Creates two tasks that operate on an interrupt driven serial port. A loopback
* connector should be used so that everything that is transmitted is also received.
* The serial port does not use any flow control. On a standard 9way 'D' connector
* Creates two tasks that operate on an interrupt driven serial port. A loopback
* connector should be used so that everything that is transmitted is also received.
* The serial port does not use any flow control. On a standard 9way 'D' connector
* pins two and three should be connected together.
*
* The first task repeatedly sends a string to a queue, character at a time. The
* serial port interrupt will empty the queue and transmit the characters. The
* The first task repeatedly sends a string to a queue, character at a time. The
* serial port interrupt will empty the queue and transmit the characters. The
* task blocks for a pseudo random period before resending the string.
*
* The second task blocks on a queue waiting for a character to be received.
* Characters received by the serial port interrupt routine are posted onto the
* queue - unblocking the task making it ready to execute. If this is then the
* highest priority task ready to run it will run immediately - with a context
* switch occurring at the end of the interrupt service routine. The task
* receiving characters is spawned with a higher priority than the task
* The second task blocks on a queue waiting for a character to be received.
* Characters received by the serial port interrupt routine are posted onto the
* queue - unblocking the task making it ready to execute. If this is then the
* highest priority task ready to run it will run immediately - with a context
* switch occurring at the end of the interrupt service routine. The task
* receiving characters is spawned with a higher priority than the task
* transmitting the characters.
*
* With the loop back connector in place, one task will transmit a string and the
* other will immediately receive it. The receiving task knows the string it
* With the loop back connector in place, one task will transmit a string and the
* other will immediately receive it. The receiving task knows the string it
* expects to receive so can detect an error.
*
* This also creates a third task. This is used to test semaphore usage from an
* ISR and does nothing interesting.
*
* ISR and does nothing interesting.
*
* \page ComTestC comtest.c
* \ingroup DemoFiles
* <HR>
*/
/*
Changes from V1.00:
+ The priority of the Rx task has been lowered. Received characters are
now processed (read from the queue) at the idle priority, allowing low
priority tasks to run evenly at times of a high communications overhead.
Changes from V1.01:
+ The Tx task now waits a pseudo random time between transmissions.
Previously a fixed period was used but this was not such a good test as
interrupts fired at regular intervals.
Changes From V1.2.0:
+ Use vSerialPutString() instead of single character puts.
+ Only stop the check variable incrementing after two consecutive errors.
Changed from V1.2.5
+ Made the Rx task 2 priorities higher than the Tx task. Previously it was
only 1. This is done to tie in better with the other demo application
tasks.
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
+ Slight modification to task priorities.
*/
* Changes from V1.00:
*
+ The priority of the Rx task has been lowered. Received characters are
+ now processed (read from the queue) at the idle priority, allowing low
+ priority tasks to run evenly at times of a high communications overhead.
+
+ Changes from V1.01:
+
+ The Tx task now waits a pseudo random time between transmissions.
+ Previously a fixed period was used but this was not such a good test as
+ interrupts fired at regular intervals.
+
+ Changes From V1.2.0:
+
+ Use vSerialPutString() instead of single character puts.
+ Only stop the check variable incrementing after two consecutive errors.
+
+ Changed from V1.2.5
+
+ Made the Rx task 2 priorities higher than the Tx task. Previously it was
+ only 1. This is done to tie in better with the other demo application
+ tasks.
+
+ Changes from V2.0.0
+
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
+ Slight modification to task priorities.
+
*/
/* Scheduler include files. */
@ -99,34 +99,34 @@ Changes from V2.0.0
#include "print.h"
/* The Tx task will transmit the sequence of characters at a pseudo random
interval. This is the maximum and minimum block time between sends. */
#define comTX_MAX_BLOCK_TIME ( ( TickType_t ) 0x15e )
#define comTX_MIN_BLOCK_TIME ( ( TickType_t ) 0xc8 )
* interval. This is the maximum and minimum block time between sends. */
#define comTX_MAX_BLOCK_TIME ( ( TickType_t ) 0x15e )
#define comTX_MIN_BLOCK_TIME ( ( TickType_t ) 0xc8 )
#define comMAX_CONSECUTIVE_ERRORS ( 2 )
#define comMAX_CONSECUTIVE_ERRORS ( 2 )
#define comSTACK_SIZE ( ( unsigned short ) 256 )
#define comSTACK_SIZE ( ( unsigned short ) 256 )
#define comRX_RELATIVE_PRIORITY ( 1 )
#define comRX_RELATIVE_PRIORITY ( 1 )
/* Handle to the com port used by both tasks. */
static xComPortHandle xPort;
/* The transmit function as described at the top of the file. */
static void vComTxTask( void *pvParameters );
static void vComTxTask( void * pvParameters );
/* The receive function as described at the top of the file. */
static void vComRxTask( void *pvParameters );
static void vComRxTask( void * pvParameters );
/* The semaphore test function as described at the top of the file. */
static void vSemTestTask( void * pvParameters );
/* The string that is repeatedly transmitted. */
const char * const pcMessageToExchange = "Send this message over and over again to check communications interrupts. "
"0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ\r\n";
const char * const pcMessageToExchange = "Send this message over and over again to check communications interrupts. "
"0123456789abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ\r\n";
/* Variables that are incremented on each cycle of each task. These are used to
check that both tasks are still executing. */
/* Variables that are incremented on each cycle of each task. These are used to
* check that both tasks are still executing. */
volatile short sTxCount = 0, sRxCount = 0, sSemCount = 0;
/* The handle to the semaphore test task. */
@ -134,212 +134,217 @@ static TaskHandle_t xSemTestTaskHandle = NULL;
/*-----------------------------------------------------------*/
void vStartComTestTasks( unsigned portBASE_TYPE uxPriority, eCOMPort ePort, eBaud eBaudRate )
void vStartComTestTasks( unsigned portBASE_TYPE uxPriority,
eCOMPort ePort,
eBaud eBaudRate )
{
const unsigned portBASE_TYPE uxBufferLength = 255;
const unsigned portBASE_TYPE uxBufferLength = 255;
/* Initialise the com port then spawn both tasks. */
xPort = xSerialPortInit( ePort, eBaudRate, serNO_PARITY, serBITS_8, serSTOP_1, uxBufferLength );
xTaskCreate( vComTxTask, "COMTx", comSTACK_SIZE, NULL, uxPriority, NULL );
xTaskCreate( vComRxTask, "COMRx", comSTACK_SIZE, NULL, uxPriority + comRX_RELATIVE_PRIORITY, NULL );
xTaskCreate( vSemTestTask, "ISRSem", comSTACK_SIZE, NULL, tskIDLE_PRIORITY, &xSemTestTaskHandle );
/* Initialise the com port then spawn both tasks. */
xPort = xSerialPortInit( ePort, eBaudRate, serNO_PARITY, serBITS_8, serSTOP_1, uxBufferLength );
xTaskCreate( vComTxTask, "COMTx", comSTACK_SIZE, NULL, uxPriority, NULL );
xTaskCreate( vComRxTask, "COMRx", comSTACK_SIZE, NULL, uxPriority + comRX_RELATIVE_PRIORITY, NULL );
xTaskCreate( vSemTestTask, "ISRSem", comSTACK_SIZE, NULL, tskIDLE_PRIORITY, &xSemTestTaskHandle );
}
/*-----------------------------------------------------------*/
static void vComTxTask( void *pvParameters )
static void vComTxTask( void * pvParameters )
{
const char * const pcTaskStartMsg = "COM Tx task started.\r\n";
TickType_t xTimeToWait;
const char * const pcTaskStartMsg = "COM Tx task started.\r\n";
TickType_t xTimeToWait;
/* Stop warnings. */
( void ) pvParameters;
/* Stop warnings. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* Send the string to the serial port. */
vSerialPutString( xPort, pcMessageToExchange, strlen( pcMessageToExchange ) );
for( ; ; )
{
/* Send the string to the serial port. */
vSerialPutString( xPort, pcMessageToExchange, strlen( pcMessageToExchange ) );
/* We have posted all the characters in the string - increment the variable
used to check that this task is still running, then wait before re-sending
the string. */
sTxCount++;
/* We have posted all the characters in the string - increment the variable
* used to check that this task is still running, then wait before re-sending
* the string. */
sTxCount++;
xTimeToWait = xTaskGetTickCount();
xTimeToWait = xTaskGetTickCount();
/* Make sure we don't wait too long... */
xTimeToWait %= comTX_MAX_BLOCK_TIME;
/* Make sure we don't wait too long... */
xTimeToWait %= comTX_MAX_BLOCK_TIME;
/* ...but we do want to wait. */
if( xTimeToWait < comTX_MIN_BLOCK_TIME )
{
xTimeToWait = comTX_MIN_BLOCK_TIME;
}
/* ...but we do want to wait. */
if( xTimeToWait < comTX_MIN_BLOCK_TIME )
{
xTimeToWait = comTX_MIN_BLOCK_TIME;
}
vTaskDelay( xTimeToWait );
}
vTaskDelay( xTimeToWait );
}
} /*lint !e715 !e818 pvParameters is required for a task function even if it is not referenced. */
/*-----------------------------------------------------------*/
static void vComRxTask( void *pvParameters )
static void vComRxTask( void * pvParameters )
{
const char * const pcTaskStartMsg = "COM Rx task started.\r\n";
const char * const pcTaskErrorMsg = "COM read error\r\n";
const char * const pcTaskRestartMsg = "COM resynced\r\n";
const char * const pcTaskTimeoutMsg = "COM Rx timed out\r\n";
const TickType_t xBlockTime = ( TickType_t ) 0xffff / portTICK_PERIOD_MS;
const char *pcExpectedChar;
portBASE_TYPE xGotChar;
char cRxedChar;
short sResyncRequired, sConsecutiveErrors, sLatchedError;
const char * const pcTaskStartMsg = "COM Rx task started.\r\n";
const char * const pcTaskErrorMsg = "COM read error\r\n";
const char * const pcTaskRestartMsg = "COM resynced\r\n";
const char * const pcTaskTimeoutMsg = "COM Rx timed out\r\n";
const TickType_t xBlockTime = ( TickType_t ) 0xffff / portTICK_PERIOD_MS;
const char * pcExpectedChar;
portBASE_TYPE xGotChar;
char cRxedChar;
short sResyncRequired, sConsecutiveErrors, sLatchedError;
/* Stop warnings. */
( void ) pvParameters;
/* Stop warnings. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The first expected character is the first character in the string. */
pcExpectedChar = pcMessageToExchange;
sResyncRequired = pdFALSE;
sConsecutiveErrors = 0;
sLatchedError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* Receive a message from the com port interrupt routine. If a message is
not yet available the call will block the task. */
xGotChar = xSerialGetChar( xPort, &cRxedChar, xBlockTime );
if( xGotChar == pdTRUE )
{
if( sResyncRequired == pdTRUE )
{
/* We got out of sequence and are waiting for the start of the next
transmission of the string. */
if( cRxedChar == '\n' )
{
/* This is the end of the message so we can start again - with
the first character in the string being the next thing we expect
to receive. */
pcExpectedChar = pcMessageToExchange;
sResyncRequired = pdFALSE;
/* The first expected character is the first character in the string. */
pcExpectedChar = pcMessageToExchange;
sResyncRequired = pdFALSE;
sConsecutiveErrors = 0;
sLatchedError = pdFALSE;
/* Queue a message for printing to say that we are going to try
again. */
vPrintDisplayMessage( &pcTaskRestartMsg );
for( ; ; )
{
/* Receive a message from the com port interrupt routine. If a message is
* not yet available the call will block the task. */
xGotChar = xSerialGetChar( xPort, &cRxedChar, xBlockTime );
/* Stop incrementing the check variable, if consecutive errors occur. */
sConsecutiveErrors++;
if( sConsecutiveErrors >= comMAX_CONSECUTIVE_ERRORS )
{
sLatchedError = pdTRUE;
}
}
}
else
{
/* We have received a character, but is it the expected character? */
if( cRxedChar != *pcExpectedChar )
{
/* This was not the expected character so post a message for
printing to say that an error has occurred. We will then wait
to resynchronise. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sResyncRequired = pdTRUE;
}
else
{
/* This was the expected character so next time we will expect
the next character in the string. Wrap back to the beginning
of the string when the null terminator has been reached. */
pcExpectedChar++;
if( *pcExpectedChar == '\0' )
{
pcExpectedChar = pcMessageToExchange;
if( xGotChar == pdTRUE )
{
if( sResyncRequired == pdTRUE )
{
/* We got out of sequence and are waiting for the start of the next
* transmission of the string. */
if( cRxedChar == '\n' )
{
/* This is the end of the message so we can start again - with
* the first character in the string being the next thing we expect
* to receive. */
pcExpectedChar = pcMessageToExchange;
sResyncRequired = pdFALSE;
/* We have got through the entire string without error. */
sConsecutiveErrors = 0;
}
}
}
/* Queue a message for printing to say that we are going to try
* again. */
vPrintDisplayMessage( &pcTaskRestartMsg );
/* Increment the count that is used to check that this task is still
running. This is only done if an error has never occurred. */
if( sLatchedError == pdFALSE )
{
sRxCount++;
}
}
else
{
vPrintDisplayMessage( &pcTaskTimeoutMsg );
}
}
/* Stop incrementing the check variable, if consecutive errors occur. */
sConsecutiveErrors++;
if( sConsecutiveErrors >= comMAX_CONSECUTIVE_ERRORS )
{
sLatchedError = pdTRUE;
}
}
}
else
{
/* We have received a character, but is it the expected character? */
if( cRxedChar != *pcExpectedChar )
{
/* This was not the expected character so post a message for
* printing to say that an error has occurred. We will then wait
* to resynchronise. */
vPrintDisplayMessage( &pcTaskErrorMsg );
sResyncRequired = pdTRUE;
}
else
{
/* This was the expected character so next time we will expect
* the next character in the string. Wrap back to the beginning
* of the string when the null terminator has been reached. */
pcExpectedChar++;
if( *pcExpectedChar == '\0' )
{
pcExpectedChar = pcMessageToExchange;
/* We have got through the entire string without error. */
sConsecutiveErrors = 0;
}
}
}
/* Increment the count that is used to check that this task is still
* running. This is only done if an error has never occurred. */
if( sLatchedError == pdFALSE )
{
sRxCount++;
}
}
else
{
vPrintDisplayMessage( &pcTaskTimeoutMsg );
}
}
} /*lint !e715 !e818 pvParameters is required for a task function even if it is not referenced. */
/*-----------------------------------------------------------*/
static void vSemTestTask( void * pvParameters )
{
const char * const pcTaskStartMsg = "ISR Semaphore test started.\r\n";
portBASE_TYPE xError = pdFALSE;
const char * const pcTaskStartMsg = "ISR Semaphore test started.\r\n";
portBASE_TYPE xError = pdFALSE;
/* Stop warnings. */
( void ) pvParameters;
/* Stop warnings. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
if( xSerialWaitForSemaphore( xPort ) )
{
if( xError == pdFALSE )
{
sSemCount++;
}
}
else
{
xError = pdTRUE;
}
}
for( ; ; )
{
if( xSerialWaitForSemaphore( xPort ) )
{
if( xError == pdFALSE )
{
sSemCount++;
}
}
else
{
xError = pdTRUE;
}
}
} /*lint !e715 !e830 !e818 pvParameters not used but function prototype must be standard for task function. */
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running. */
portBASE_TYPE xAreComTestTasksStillRunning( void )
{
static short sLastTxCount = 0, sLastRxCount = 0, sLastSemCount = 0;
portBASE_TYPE xReturn;
static short sLastTxCount = 0, sLastRxCount = 0, sLastSemCount = 0;
portBASE_TYPE xReturn;
/* Not too worried about mutual exclusion on these variables as they are 16
bits and we are only reading them. We also only care to see if they have
changed or not. */
/* Not too worried about mutual exclusion on these variables as they are 16
* bits and we are only reading them. We also only care to see if they have
* changed or not. */
if( ( sTxCount == sLastTxCount ) || ( sRxCount == sLastRxCount ) || ( sSemCount == sLastSemCount ) )
{
xReturn = pdFALSE;
}
else
{
xReturn = pdTRUE;
}
if( ( sTxCount == sLastTxCount ) || ( sRxCount == sLastRxCount ) || ( sSemCount == sLastSemCount ) )
{
xReturn = pdFALSE;
}
else
{
xReturn = pdTRUE;
}
sLastTxCount = sTxCount;
sLastRxCount = sRxCount;
sLastSemCount = sSemCount;
sLastTxCount = sTxCount;
sLastRxCount = sRxCount;
sLastSemCount = sSemCount;
return xReturn;
return xReturn;
}
/*-----------------------------------------------------------*/
void vComTestUnsuspendTask( void )
{
/* The task that is suspended on the semaphore will be referenced from the
Suspended list as it is blocking indefinitely. This call just checks that
the kernel correctly detects this and does not attempt to unsuspend the
task. */
xTaskResumeFromISR( xSemTestTaskHandle );
/* The task that is suspended on the semaphore will be referenced from the
* Suspended list as it is blocking indefinitely. This call just checks that
* the kernel correctly detects this and does not attempt to unsuspend the
* task. */
xTaskResumeFromISR( xSemTestTaskHandle );
}

101
FreeRTOS/Demo/Common/Full/death.c
View file

@ -25,17 +25,17 @@
*/
/**
* Create a single persistent task which periodically dynamically creates another
* four tasks. The original task is called the creator task, the four tasks it
* Create a single persistent task which periodically dynamically creates another
* four tasks. The original task is called the creator task, the four tasks it
* creates are called suicidal tasks.
*
* Two of the created suicidal tasks kill one other suicidal task before killing
* themselves - leaving just the original task remaining.
* Two of the created suicidal tasks kill one other suicidal task before killing
* themselves - leaving just the original task remaining.
*
* The creator task must be spawned after all of the other demo application tasks
* as it keeps a check on the number of tasks under the scheduler control. The
* number of tasks it expects to see running should never be greater than the
* number of tasks that were in existence when the creator task was spawned, plus
* The creator task must be spawned after all of the other demo application tasks
* as it keeps a check on the number of tasks under the scheduler control. The
* number of tasks it expects to see running should never be greater than the
* number of tasks that were in existence when the creator task was spawned, plus
* one set of four suicidal tasks. If this number is exceeded an error is flagged.
*
* \page DeathC death.c
@ -44,11 +44,11 @@
*/
/*
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
*/
* Changes from V2.0.0
*
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
*/
#include <stdlib.h>
@ -60,66 +60,66 @@ Changes from V2.0.0
#include "death.h"
#include "print.h"
#define deathSTACK_SIZE ( ( unsigned short ) 512 )
#define deathSTACK_SIZE ( ( unsigned short ) 512 )
/* The task originally created which is responsible for periodically dynamically
creating another four tasks. */
static void vCreateTasks( void *pvParameters );
/* The task originally created which is responsible for periodically dynamically
* creating another four tasks. */
static void vCreateTasks( void * pvParameters );
/* The task function of the dynamically created tasks. */
static void vSuicidalTask( void *pvParameters );
static void vSuicidalTask( void * pvParameters );
/* A variable which is incremented every time the dynamic tasks are created. This
is used to check that the task is still running. */
/* A variable which is incremented every time the dynamic tasks are created. This
* is used to check that the task is still running. */
static volatile short sCreationCount = 0;
/* Used to store the number of tasks that were originally running so the creator
task can tell if any of the suicidal tasks have failed to die. */
/* Used to store the number of tasks that were originally running so the creator
* task can tell if any of the suicidal tasks have failed to die. */
static volatile unsigned portBASE_TYPE uxTasksRunningAtStart = 0;
static const unsigned portBASE_TYPE uxMaxNumberOfExtraTasksRunning = 5;
/* Used to store a handle to the tasks that should be killed by a suicidal task,
before it kills itself. */
/* Used to store a handle to the tasks that should be killed by a suicidal task,
* before it kills itself. */
TaskHandle_t xCreatedTask1, xCreatedTask2;
/*-----------------------------------------------------------*/
void vCreateSuicidalTasks( unsigned portBASE_TYPE uxPriority )
{
unsigned portBASE_TYPE *puxPriority;
unsigned portBASE_TYPE * puxPriority;
/* Create the Creator tasks - passing in as a parameter the priority at which
the suicidal tasks should be created. */
/* Create the Creator tasks - passing in as a parameter the priority at which
* the suicidal tasks should be created. */
puxPriority = ( unsigned portBASE_TYPE * ) pvPortMalloc( sizeof( unsigned portBASE_TYPE ) );
*puxPriority = uxPriority;
xTaskCreate( vCreateTasks, "CREATOR", deathSTACK_SIZE, ( void * ) puxPriority, uxPriority, NULL );
/* Record the number of tasks that are running now so we know if any of the
suicidal tasks have failed to be killed. */
/* Record the number of tasks that are running now so we know if any of the
* suicidal tasks have failed to be killed. */
uxTasksRunningAtStart = uxTaskGetNumberOfTasks();
}
/*-----------------------------------------------------------*/
static void vSuicidalTask( void *pvParameters )
static void vSuicidalTask( void * pvParameters )
{
portDOUBLE d1, d2;
TaskHandle_t xTaskToKill;
const TickType_t xDelay = ( TickType_t ) 500 / portTICK_PERIOD_MS;
portDOUBLE d1, d2;
TaskHandle_t xTaskToKill;
const TickType_t xDelay = ( TickType_t ) 500 / portTICK_PERIOD_MS;
if( pvParameters != NULL )
{
/* This task is periodically created four times. Tow created tasks are
passed a handle to the other task so it can kill it before killing itself.
The other task is passed in null. */
xTaskToKill = *( TaskHandle_t* )pvParameters;
/* This task is periodically created four times. Tow created tasks are
* passed a handle to the other task so it can kill it before killing itself.
* The other task is passed in null. */
xTaskToKill = *( TaskHandle_t * ) pvParameters;
}
else
{
xTaskToKill = NULL;
}
for( ;; )
for( ; ; )
{
/* Do something random just to use some stack and registers. */
d1 = 2.4;
@ -137,14 +137,14 @@ const TickType_t xDelay = ( TickType_t ) 500 / portTICK_PERIOD_MS;
vTaskDelete( NULL );
}
}
}/*lint !e818 !e550 Function prototype must be as per standard for task functions. */
} /*lint !e818 !e550 Function prototype must be as per standard for task functions. */
/*-----------------------------------------------------------*/
static void vCreateTasks( void *pvParameters )
static void vCreateTasks( void * pvParameters )
{
const TickType_t xDelay = ( TickType_t ) 1000 / portTICK_PERIOD_MS;
unsigned portBASE_TYPE uxPriority;
const char * const pcTaskStartMsg = "Create task started.\r\n";
const TickType_t xDelay = ( TickType_t ) 1000 / portTICK_PERIOD_MS;
unsigned portBASE_TYPE uxPriority;
const char * const pcTaskStartMsg = "Create task started.\r\n";
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
@ -152,7 +152,7 @@ const char * const pcTaskStartMsg = "Create task started.\r\n";
uxPriority = *( unsigned portBASE_TYPE * ) pvParameters;
vPortFree( pvParameters );
for( ;; )
for( ; ; )
{
/* Just loop round, delaying then creating the four suicidal tasks. */
vTaskDelay( xDelay );
@ -168,18 +168,19 @@ const char * const pcTaskStartMsg = "Create task started.\r\n";
}
/*-----------------------------------------------------------*/
/* This is called to check that the creator task is still running and that there
are not any more than four extra tasks. */
/* This is called to check that the creator task is still running and that there
* are not any more than four extra tasks. */
portBASE_TYPE xIsCreateTaskStillRunning( void )
{
static short sLastCreationCount = 0;
short sReturn = pdTRUE;
unsigned portBASE_TYPE uxTasksRunningNow;
static short sLastCreationCount = 0;
short sReturn = pdTRUE;
unsigned portBASE_TYPE uxTasksRunningNow;
if( sLastCreationCount == sCreationCount )
{
sReturn = pdFALSE;
}
sLastCreationCount = sCreationCount;
uxTasksRunningNow = uxTaskGetNumberOfTasks();
@ -199,5 +200,3 @@ unsigned portBASE_TYPE uxTasksRunningNow;
return sReturn;
}

697
FreeRTOS/Demo/Common/Full/dynamic.c
View file

@ -26,31 +26,31 @@
*/
/**
* The first test creates three tasks - two counter tasks (one continuous count
* and one limited count) and one controller. A "count" variable is shared
* between all three tasks. The two counter tasks should never be in a "ready"
* state at the same time. The controller task runs at the same priority as
* the continuous count task, and at a lower priority than the limited count
* The first test creates three tasks - two counter tasks (one continuous count
* and one limited count) and one controller. A "count" variable is shared
* between all three tasks. The two counter tasks should never be in a "ready"
* state at the same time. The controller task runs at the same priority as
* the continuous count task, and at a lower priority than the limited count
* task.
*
* One counter task loops indefinitely, incrementing the shared count variable
* on each iteration. To ensure it has exclusive access to the variable it
* raises it's priority above that of the controller task before each
* raises it's priority above that of the controller task before each
* increment, lowering it again to it's original priority before starting the
* next iteration.
*
* The other counter task increments the shared count variable on each
* iteration of it's loop until the count has reached a limit of 0xff - at
* which point it suspends itself. It will not start a new loop until the
* controller task has made it "ready" again by calling vTaskResume ().
* This second counter task operates at a higher priority than controller
* task so does not need to worry about mutual exclusion of the counter
* which point it suspends itself. It will not start a new loop until the
* controller task has made it "ready" again by calling vTaskResume ().
* This second counter task operates at a higher priority than controller
* task so does not need to worry about mutual exclusion of the counter
* variable.
*
* The controller task is in two sections. The first section controls and
* monitors the continuous count task. When this section is operational the
* limited count task is suspended. Likewise, the second section controls
* and monitors the limited count task. When this section is operational the
* monitors the continuous count task. When this section is operational the
* limited count task is suspended. Likewise, the second section controls
* and monitors the limited count task. When this section is operational the
* continuous count task is suspended.
*
* In the first section the controller task first takes a copy of the shared
@ -60,11 +60,11 @@
* the continuous count task will execute and increment the shared variable.
* When the controller task wakes it checks that the continuous count task
* has executed by comparing the copy of the shared variable with its current
* value. This time, to ensure mutual exclusion, the scheduler itself is
* suspended with a call to vTaskSuspendAll (). This is for demonstration
* value. This time, to ensure mutual exclusion, the scheduler itself is
* suspended with a call to vTaskSuspendAll (). This is for demonstration
* purposes only and is not a recommended technique due to its inefficiency.
*
* After a fixed number of iterations the controller task suspends the
* After a fixed number of iterations the controller task suspends the
* continuous count task, and moves on to its second section.
*
* At the start of the second section the shared variable is cleared to zero.
@ -76,7 +76,7 @@
* a check on the shared variable to ensure everything is as expected.
*
*
* The second test consists of a couple of very simple tasks that post onto a
* The second test consists of a couple of very simple tasks that post onto a
* queue while the scheduler is suspended. This test was added to test parts
* of the scheduler not exercised by the first test.
*
@ -91,20 +91,20 @@
*/
/*
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
+ Added a second, simple test that uses the functions
vQueueReceiveWhenSuspendedTask() and vQueueSendWhenSuspendedTask().
Changes from V3.1.1
+ Added a third simple test that uses the vTaskPrioritySet() function
while the scheduler is suspended.
+ Modified the controller task slightly to test the calling of
vTaskResumeAll() while the scheduler is suspended.
*/
* Changes from V2.0.0
*
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
+ Added a second, simple test that uses the functions
+ vQueueReceiveWhenSuspendedTask() and vQueueSendWhenSuspendedTask().
+
+ Changes from V3.1.1
+
+ Added a third simple test that uses the vTaskPrioritySet() function
+ while the scheduler is suspended.
+ Modified the controller task slightly to test the calling of
+ vTaskResumeAll() while the scheduler is suspended.
*/
#include <stdlib.h>
@ -127,42 +127,42 @@ static void vContinuousIncrementTask( void * pvParameters );
static void vCounterControlTask( void * pvParameters );
/* The simple test functions that check sending and receiving while the
scheduler is suspended. */
static void vQueueReceiveWhenSuspendedTask( void *pvParameters );
static void vQueueSendWhenSuspendedTask( void *pvParameters );
* scheduler is suspended. */
static void vQueueReceiveWhenSuspendedTask( void * pvParameters );
static void vQueueSendWhenSuspendedTask( void * pvParameters );
/* The simple test functions that check raising and lowering of task priorities
while the scheduler is suspended. */
static void prvChangePriorityWhenSuspendedTask( void *pvParameters );
static void prvChangePriorityHelperTask( void *pvParameters );
* while the scheduler is suspended. */
static void prvChangePriorityWhenSuspendedTask( void * pvParameters );
static void prvChangePriorityHelperTask( void * pvParameters );
/* Demo task specific constants. */
#define priSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
#define priSLEEP_TIME ( ( TickType_t ) 50 )
#define priLOOPS ( 5 )
#define priMAX_COUNT ( ( unsigned long ) 0xff )
#define priNO_BLOCK ( ( TickType_t ) 0 )
#define priSUSPENDED_QUEUE_LENGTH ( 1 )
#define priSTACK_SIZE ( ( unsigned short ) configMINIMAL_STACK_SIZE )
#define priSLEEP_TIME ( ( TickType_t ) 50 )
#define priLOOPS ( 5 )
#define priMAX_COUNT ( ( unsigned long ) 0xff )
#define priNO_BLOCK ( ( TickType_t ) 0 )
#define priSUSPENDED_QUEUE_LENGTH ( 1 )
/*-----------------------------------------------------------*/
/* Handles to the two counter tasks. These could be passed in as parameters
to the controller task to prevent them having to be file scope. */
* to the controller task to prevent them having to be file scope. */
static TaskHandle_t xContinuousIncrementHandle, xLimitedIncrementHandle, xChangePriorityWhenSuspendedHandle;
/* The shared counter variable. This is passed in as a parameter to the two
counter variables for demonstration purposes. */
/* The shared counter variable. This is passed in as a parameter to the two
* counter variables for demonstration purposes. */
static unsigned long ulCounter;
/* Variable used in a similar way by the test that checks the raising and
lowering of task priorities while the scheduler is suspended. */
* lowering of task priorities while the scheduler is suspended. */
static unsigned long ulPrioritySetCounter;
/* Variables used to check that the tasks are still operating without error.
Each complete iteration of the controller task increments this variable
provided no errors have been found. The variable maintaining the same value
is therefore indication of an error. */
* Each complete iteration of the controller task increments this variable
* provided no errors have been found. The variable maintaining the same value
* is therefore indication of an error. */
static unsigned short usCheckVariable = ( unsigned short ) 0;
static portBASE_TYPE xSuspendedQueueSendError = pdFALSE;
static portBASE_TYPE xSuspendedQueueReceiveError = pdFALSE;
@ -172,49 +172,50 @@ static portBASE_TYPE xPriorityRaiseWhenSuspendedError = pdFALSE;
QueueHandle_t xSuspendedTestQueue;
/*-----------------------------------------------------------*/
/*
* Start the seven tasks as described at the top of the file.
* Note that the limited count task is given a higher priority.
*/
void vStartDynamicPriorityTasks( void )
{
xSuspendedTestQueue = xQueueCreate( priSUSPENDED_QUEUE_LENGTH, sizeof( unsigned long ) );
xTaskCreate( vContinuousIncrementTask, "CONT_INC", priSTACK_SIZE, ( void * ) &ulCounter, tskIDLE_PRIORITY, &xContinuousIncrementHandle );
xTaskCreate( vLimitedIncrementTask, "LIM_INC", priSTACK_SIZE, ( void * ) &ulCounter, tskIDLE_PRIORITY + 1, &xLimitedIncrementHandle );
xTaskCreate( vCounterControlTask, "C_CTRL", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( vQueueSendWhenSuspendedTask, "SUSP_SEND", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( vQueueReceiveWhenSuspendedTask, "SUSP_RECV", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( prvChangePriorityWhenSuspendedTask, "1st_P_CHANGE", priSTACK_SIZE, NULL, tskIDLE_PRIORITY + 1, NULL );
xTaskCreate( prvChangePriorityHelperTask, "2nd_P_CHANGE", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, &xChangePriorityWhenSuspendedHandle );
xSuspendedTestQueue = xQueueCreate( priSUSPENDED_QUEUE_LENGTH, sizeof( unsigned long ) );
xTaskCreate( vContinuousIncrementTask, "CONT_INC", priSTACK_SIZE, ( void * ) &ulCounter, tskIDLE_PRIORITY, &xContinuousIncrementHandle );
xTaskCreate( vLimitedIncrementTask, "LIM_INC", priSTACK_SIZE, ( void * ) &ulCounter, tskIDLE_PRIORITY + 1, &xLimitedIncrementHandle );
xTaskCreate( vCounterControlTask, "C_CTRL", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( vQueueSendWhenSuspendedTask, "SUSP_SEND", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( vQueueReceiveWhenSuspendedTask, "SUSP_RECV", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
xTaskCreate( prvChangePriorityWhenSuspendedTask, "1st_P_CHANGE", priSTACK_SIZE, NULL, tskIDLE_PRIORITY + 1, NULL );
xTaskCreate( prvChangePriorityHelperTask, "2nd_P_CHANGE", priSTACK_SIZE, NULL, tskIDLE_PRIORITY, &xChangePriorityWhenSuspendedHandle );
}
/*-----------------------------------------------------------*/
/*
* Just loops around incrementing the shared variable until the limit has been
* reached. Once the limit has been reached it suspends itself.
* reached. Once the limit has been reached it suspends itself.
*/
static void vLimitedIncrementTask( void * pvParameters )
{
unsigned long *pulCounter;
unsigned long * pulCounter;
/* Take a pointer to the shared variable from the parameters passed into
the task. */
pulCounter = ( unsigned long * ) pvParameters;
/* Take a pointer to the shared variable from the parameters passed into
* the task. */
pulCounter = ( unsigned long * ) pvParameters;
/* This will run before the control task, so the first thing it does is
suspend - the control task will resume it when ready. */
vTaskSuspend( NULL );
/* This will run before the control task, so the first thing it does is
* suspend - the control task will resume it when ready. */
vTaskSuspend( NULL );
for( ;; )
{
/* Just count up to a value then suspend. */
( *pulCounter )++;
if( *pulCounter >= priMAX_COUNT )
{
vTaskSuspend( NULL );
}
}
for( ; ; )
{
/* Just count up to a value then suspend. */
( *pulCounter )++;
if( *pulCounter >= priMAX_COUNT )
{
vTaskSuspend( NULL );
}
}
}
/*-----------------------------------------------------------*/
@ -224,29 +225,29 @@ unsigned long *pulCounter;
*/
static void vContinuousIncrementTask( void * pvParameters )
{
unsigned long *pulCounter;
unsigned portBASE_TYPE uxOurPriority;
unsigned long * pulCounter;
unsigned portBASE_TYPE uxOurPriority;
/* Take a pointer to the shared variable from the parameters passed into
the task. */
pulCounter = ( unsigned long * ) pvParameters;
/* Take a pointer to the shared variable from the parameters passed into
* the task. */
pulCounter = ( unsigned long * ) pvParameters;
/* Query our priority so we can raise it when exclusive access to the
shared variable is required. */
uxOurPriority = uxTaskPriorityGet( NULL );
/* Query our priority so we can raise it when exclusive access to the
* shared variable is required. */
uxOurPriority = uxTaskPriorityGet( NULL );
for( ;; )
{
/* Raise our priority above the controller task to ensure a context
switch does not occur while we are accessing this variable. */
vTaskPrioritySet( NULL, uxOurPriority + 1 );
( *pulCounter )++;
vTaskPrioritySet( NULL, uxOurPriority );
for( ; ; )
{
/* Raise our priority above the controller task to ensure a context
* switch does not occur while we are accessing this variable. */
vTaskPrioritySet( NULL, uxOurPriority + 1 );
( *pulCounter )++;
vTaskPrioritySet( NULL, uxOurPriority );
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
}
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
}
}
/*-----------------------------------------------------------*/
@ -255,324 +256,320 @@ unsigned portBASE_TYPE uxOurPriority;
*/
static void vCounterControlTask( void * pvParameters )
{
unsigned long ulLastCounter;
short sLoops;
short sError = pdFALSE;
const char * const pcTaskStartMsg = "Priority manipulation tasks started.\r\n";
const char * const pcTaskFailMsg = "Priority manipulation Task Failed\r\n";
unsigned long ulLastCounter;
short sLoops;
short sError = pdFALSE;
const char * const pcTaskStartMsg = "Priority manipulation tasks started.\r\n";
const char * const pcTaskFailMsg = "Priority manipulation Task Failed\r\n";
/* Just to stop warning messages. */
( void ) pvParameters;
/* Just to stop warning messages. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* Start with the counter at zero. */
ulCounter = ( unsigned long ) 0;
for( ; ; )
{
/* Start with the counter at zero. */
ulCounter = ( unsigned long ) 0;
/* First section : */
/* First section : */
/* Check the continuous count task is running. */
for( sLoops = 0; sLoops < priLOOPS; sLoops++ )
{
/* Suspend the continuous count task so we can take a mirror of the
shared variable without risk of corruption. */
vTaskSuspend( xContinuousIncrementHandle );
ulLastCounter = ulCounter;
vTaskResume( xContinuousIncrementHandle );
/* Now delay to ensure the other task has processor time. */
vTaskDelay( priSLEEP_TIME );
/* Check the continuous count task is running. */
for( sLoops = 0; sLoops < priLOOPS; sLoops++ )
{
/* Suspend the continuous count task so we can take a mirror of the
* shared variable without risk of corruption. */
vTaskSuspend( xContinuousIncrementHandle );
ulLastCounter = ulCounter;
vTaskResume( xContinuousIncrementHandle );
/* Check the shared variable again. This time to ensure mutual
exclusion the whole scheduler will be locked. This is just for
demo purposes! */
vTaskSuspendAll();
{
if( ulLastCounter == ulCounter )
{
/* The shared variable has not changed. There is a problem
with the continuous count task so flag an error. */
sError = pdTRUE;
xTaskResumeAll();
vPrintDisplayMessage( &pcTaskFailMsg );
vTaskSuspendAll();
}
}
xTaskResumeAll();
}
/* Now delay to ensure the other task has processor time. */
vTaskDelay( priSLEEP_TIME );
/* Check the shared variable again. This time to ensure mutual
* exclusion the whole scheduler will be locked. This is just for
* demo purposes! */
vTaskSuspendAll();
{
if( ulLastCounter == ulCounter )
{
/* The shared variable has not changed. There is a problem
* with the continuous count task so flag an error. */
sError = pdTRUE;
xTaskResumeAll();
vPrintDisplayMessage( &pcTaskFailMsg );
vTaskSuspendAll();
}
}
xTaskResumeAll();
}
/* Second section: */
/* Second section: */
/* Suspend the continuous counter task so it stops accessing the shared variable. */
vTaskSuspend( xContinuousIncrementHandle );
/* Suspend the continuous counter task so it stops accessing the shared variable. */
vTaskSuspend( xContinuousIncrementHandle );
/* Reset the variable. */
ulCounter = ( unsigned long ) 0;
/* Reset the variable. */
ulCounter = ( unsigned long ) 0;
/* Resume the limited count task which has a higher priority than us.
We should therefore not return from this call until the limited count
task has suspended itself with a known value in the counter variable.
The scheduler suspension is not necessary but is included for test
purposes. */
vTaskSuspendAll();
vTaskResume( xLimitedIncrementHandle );
xTaskResumeAll();
/* Resume the limited count task which has a higher priority than us.
* We should therefore not return from this call until the limited count
* task has suspended itself with a known value in the counter variable.
* The scheduler suspension is not necessary but is included for test
* purposes. */
vTaskSuspendAll();
vTaskResume( xLimitedIncrementHandle );
xTaskResumeAll();
/* Does the counter variable have the expected value? */
if( ulCounter != priMAX_COUNT )
{
sError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
/* Does the counter variable have the expected value? */
if( ulCounter != priMAX_COUNT )
{
sError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
if( sError == pdFALSE )
{
/* If no errors have occurred then increment the check variable. */
portENTER_CRITICAL();
usCheckVariable++;
portEXIT_CRITICAL();
}
if( sError == pdFALSE )
{
/* If no errors have occurred then increment the check variable. */
portENTER_CRITICAL();
usCheckVariable++;
portEXIT_CRITICAL();
}
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
/* Resume the continuous count task and do it all again. */
vTaskResume( xContinuousIncrementHandle );
}
/* Resume the continuous count task and do it all again. */
vTaskResume( xContinuousIncrementHandle );
}
}
/*-----------------------------------------------------------*/
static void vQueueSendWhenSuspendedTask( void *pvParameters )
static void vQueueSendWhenSuspendedTask( void * pvParameters )
{
static unsigned long ulValueToSend = ( unsigned long ) 0;
const char * const pcTaskStartMsg = "Queue send while suspended task started.\r\n";
const char * const pcTaskFailMsg = "Queue send while suspended failed.\r\n";
static unsigned long ulValueToSend = ( unsigned long ) 0;
const char * const pcTaskStartMsg = "Queue send while suspended task started.\r\n";
const char * const pcTaskFailMsg = "Queue send while suspended failed.\r\n";
/* Just to stop warning messages. */
( void ) pvParameters;
/* Just to stop warning messages. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
vTaskSuspendAll();
{
/* We must not block while the scheduler is suspended! */
if( xQueueSend( xSuspendedTestQueue, ( void * ) &ulValueToSend, priNO_BLOCK ) != pdTRUE )
{
if( xSuspendedQueueSendError == pdFALSE )
{
xTaskResumeAll();
vPrintDisplayMessage( &pcTaskFailMsg );
vTaskSuspendAll();
}
for( ; ; )
{
vTaskSuspendAll();
{
/* We must not block while the scheduler is suspended! */
if( xQueueSend( xSuspendedTestQueue, ( void * ) &ulValueToSend, priNO_BLOCK ) != pdTRUE )
{
if( xSuspendedQueueSendError == pdFALSE )
{
xTaskResumeAll();
vPrintDisplayMessage( &pcTaskFailMsg );
vTaskSuspendAll();
}
xSuspendedQueueSendError = pdTRUE;
}
}
xTaskResumeAll();
xSuspendedQueueSendError = pdTRUE;
}
}
xTaskResumeAll();
vTaskDelay( priSLEEP_TIME );
vTaskDelay( priSLEEP_TIME );
++ulValueToSend;
}
++ulValueToSend;
}
}
/*-----------------------------------------------------------*/
static void vQueueReceiveWhenSuspendedTask( void *pvParameters )
static void vQueueReceiveWhenSuspendedTask( void * pvParameters )
{
static unsigned long ulExpectedValue = ( unsigned long ) 0, ulReceivedValue;
const char * const pcTaskStartMsg = "Queue receive while suspended task started.\r\n";
const char * const pcTaskFailMsg = "Queue receive while suspended failed.\r\n";
portBASE_TYPE xGotValue;
static unsigned long ulExpectedValue = ( unsigned long ) 0, ulReceivedValue;
const char * const pcTaskStartMsg = "Queue receive while suspended task started.\r\n";
const char * const pcTaskFailMsg = "Queue receive while suspended failed.\r\n";
portBASE_TYPE xGotValue;
/* Just to stop warning messages. */
( void ) pvParameters;
/* Just to stop warning messages. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
do
{
/* Suspending the scheduler here is fairly pointless and
undesirable for a normal application. It is done here purely
to test the scheduler. The inner xTaskResumeAll() should
never return pdTRUE as the scheduler is still locked by the
outer call. */
vTaskSuspendAll();
{
vTaskSuspendAll();
{
xGotValue = xQueueReceive( xSuspendedTestQueue, ( void * ) &ulReceivedValue, priNO_BLOCK );
}
if( xTaskResumeAll() )
{
xSuspendedQueueReceiveError = pdTRUE;
}
}
xTaskResumeAll();
for( ; ; )
{
do
{
/* Suspending the scheduler here is fairly pointless and
* undesirable for a normal application. It is done here purely
* to test the scheduler. The inner xTaskResumeAll() should
* never return pdTRUE as the scheduler is still locked by the
* outer call. */
vTaskSuspendAll();
{
vTaskSuspendAll();
{
xGotValue = xQueueReceive( xSuspendedTestQueue, ( void * ) &ulReceivedValue, priNO_BLOCK );
}
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
if( xTaskResumeAll() )
{
xSuspendedQueueReceiveError = pdTRUE;
}
}
xTaskResumeAll();
} while( xGotValue == pdFALSE );
#if configUSE_PREEMPTION == 0
taskYIELD();
#endif
} while( xGotValue == pdFALSE );
if( ulReceivedValue != ulExpectedValue )
{
if( xSuspendedQueueReceiveError == pdFALSE )
{
vPrintDisplayMessage( &pcTaskFailMsg );
}
xSuspendedQueueReceiveError = pdTRUE;
}
if( ulReceivedValue != ulExpectedValue )
{
if( xSuspendedQueueReceiveError == pdFALSE )
{
vPrintDisplayMessage( &pcTaskFailMsg );
}
++ulExpectedValue;
}
xSuspendedQueueReceiveError = pdTRUE;
}
++ulExpectedValue;
}
}
/*-----------------------------------------------------------*/
static void prvChangePriorityWhenSuspendedTask( void *pvParameters )
static void prvChangePriorityWhenSuspendedTask( void * pvParameters )
{
const char * const pcTaskStartMsg = "Priority change when suspended task started.\r\n";
const char * const pcTaskFailMsg = "Priority change when suspended task failed.\r\n";
const char * const pcTaskStartMsg = "Priority change when suspended task started.\r\n";
const char * const pcTaskFailMsg = "Priority change when suspended task failed.\r\n";
/* Just to stop warning messages. */
( void ) pvParameters;
/* Just to stop warning messages. */
( void ) pvParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* Start with the counter at 0 so we know what the counter should be
when we check it next. */
ulPrioritySetCounter = ( unsigned long ) 0;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Resume the helper task. At this time it has a priority lower than
ours so no context switch should occur. */
vTaskResume( xChangePriorityWhenSuspendedHandle );
for( ; ; )
{
/* Start with the counter at 0 so we know what the counter should be
* when we check it next. */
ulPrioritySetCounter = ( unsigned long ) 0;
/* Check to ensure the task just resumed has not executed. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 0 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
/* Resume the helper task. At this time it has a priority lower than
* ours so no context switch should occur. */
vTaskResume( xChangePriorityWhenSuspendedHandle );
/* Now try raising the priority while the scheduler is suspended. */
vTaskSuspendAll();
{
vTaskPrioritySet( xChangePriorityWhenSuspendedHandle, ( configMAX_PRIORITIES - 1 ) );
/* Check to ensure the task just resumed has not executed. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 0 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
/* Again, even though the helper task has a priority greater than
ours, it should not have executed yet because the scheduler is
suspended. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 0 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
}
xTaskResumeAll();
/* Now the scheduler has been resumed the helper task should
immediately preempt us and execute. When it executes it will increment
the ulPrioritySetCounter exactly once before suspending itself.
/* Now try raising the priority while the scheduler is suspended. */
vTaskSuspendAll();
{
vTaskPrioritySet( xChangePriorityWhenSuspendedHandle, ( configMAX_PRIORITIES - 1 ) );
We should now always find the counter set to 1. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 1 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
/* Again, even though the helper task has a priority greater than
* ours, it should not have executed yet because the scheduler is
* suspended. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 0 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
}
xTaskResumeAll();
/* Delay until we try this again. */
vTaskDelay( priSLEEP_TIME * 2 );
/* Set the priority of the helper task back ready for the next
execution of this task. */
vTaskSuspendAll();
vTaskPrioritySet( xChangePriorityWhenSuspendedHandle, tskIDLE_PRIORITY );
xTaskResumeAll();
}
/* Now the scheduler has been resumed the helper task should
* immediately preempt us and execute. When it executes it will increment
* the ulPrioritySetCounter exactly once before suspending itself.
*
* We should now always find the counter set to 1. */
portENTER_CRITICAL();
{
if( ulPrioritySetCounter != ( unsigned long ) 1 )
{
xPriorityRaiseWhenSuspendedError = pdTRUE;
vPrintDisplayMessage( &pcTaskFailMsg );
}
}
portEXIT_CRITICAL();
/* Delay until we try this again. */
vTaskDelay( priSLEEP_TIME * 2 );
/* Set the priority of the helper task back ready for the next
* execution of this task. */
vTaskSuspendAll();
vTaskPrioritySet( xChangePriorityWhenSuspendedHandle, tskIDLE_PRIORITY );
xTaskResumeAll();
}
}
/*-----------------------------------------------------------*/
static void prvChangePriorityHelperTask( void *pvParameters )
static void prvChangePriorityHelperTask( void * pvParameters )
{
/* Just to stop warning messages. */
( void ) pvParameters;
/* Just to stop warning messages. */
( void ) pvParameters;
for( ;; )
{
/* This is the helper task for prvChangePriorityWhenSuspendedTask().
It has it's priority raised and lowered. When it runs it simply
increments the counter then suspends itself again. This allows
prvChangePriorityWhenSuspendedTask() to know how many times it has
executed. */
ulPrioritySetCounter++;
vTaskSuspend( NULL );
}
for( ; ; )
{
/* This is the helper task for prvChangePriorityWhenSuspendedTask().
* It has it's priority raised and lowered. When it runs it simply
* increments the counter then suspends itself again. This allows
* prvChangePriorityWhenSuspendedTask() to know how many times it has
* executed. */
ulPrioritySetCounter++;
vTaskSuspend( NULL );
}
}
/*-----------------------------------------------------------*/
/* Called to check that all the created tasks are still running without error. */
portBASE_TYPE xAreDynamicPriorityTasksStillRunning( void )
{
/* Keep a history of the check variables so we know if it has been incremented
since the last call. */
static unsigned short usLastTaskCheck = ( unsigned short ) 0;
portBASE_TYPE xReturn = pdTRUE;
/* Keep a history of the check variables so we know if it has been incremented
* since the last call. */
static unsigned short usLastTaskCheck = ( unsigned short ) 0;
portBASE_TYPE xReturn = pdTRUE;
/* Check the tasks are still running by ensuring the check variable
is still incrementing. */
/* Check the tasks are still running by ensuring the check variable
* is still incrementing. */
if( usCheckVariable == usLastTaskCheck )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
if( usCheckVariable == usLastTaskCheck )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
if( xSuspendedQueueSendError == pdTRUE )
{
xReturn = pdFALSE;
}
if( xSuspendedQueueSendError == pdTRUE )
{
xReturn = pdFALSE;
}
if( xSuspendedQueueReceiveError == pdTRUE )
{
xReturn = pdFALSE;
}
if( xSuspendedQueueReceiveError == pdTRUE )
{
xReturn = pdFALSE;
}
if( xPriorityRaiseWhenSuspendedError == pdTRUE )
{
xReturn = pdFALSE;
}
if( xPriorityRaiseWhenSuspendedError == pdTRUE )
{
xReturn = pdFALSE;
}
usLastTaskCheck = usCheckVariable;
return xReturn;
usLastTaskCheck = usCheckVariable;
return xReturn;
}

469
FreeRTOS/Demo/Common/Full/events.c
View file

@ -60,309 +60,310 @@
#include "print.h"
/* Demo specific constants. */
#define evtSTACK_SIZE ( ( unsigned portBASE_TYPE ) configMINIMAL_STACK_SIZE )
#define evtNUM_TASKS ( 4 )
#define evtQUEUE_LENGTH ( ( unsigned portBASE_TYPE ) 3 )
#define evtNO_DELAY 0
#define evtSTACK_SIZE ( ( unsigned portBASE_TYPE ) configMINIMAL_STACK_SIZE )
#define evtNUM_TASKS ( 4 )
#define evtQUEUE_LENGTH ( ( unsigned portBASE_TYPE ) 3 )
#define evtNO_DELAY 0
/* Just indexes used to uniquely identify the tasks. Note that two tasks are
'highest' priority. */
#define evtHIGHEST_PRIORITY_INDEX_2 3
#define evtHIGHEST_PRIORITY_INDEX_1 2
#define evtMEDIUM_PRIORITY_INDEX 1
#define evtLOWEST_PRIORITY_INDEX 0
* 'highest' priority. */
#define evtHIGHEST_PRIORITY_INDEX_2 3
#define evtHIGHEST_PRIORITY_INDEX_1 2
#define evtMEDIUM_PRIORITY_INDEX 1
#define evtLOWEST_PRIORITY_INDEX 0
/* Each event task increments one of these counters each time it reads data
from the queue. */
* from the queue. */
static volatile portBASE_TYPE xTaskCounters[ evtNUM_TASKS ] = { 0, 0, 0, 0 };
/* Each time the controlling task posts onto the queue it increments the
expected count of the task that it expected to read the data from the queue
(i.e. the task with the highest priority that should be blocked on the queue).
xExpectedTaskCounters are incremented from the controlling task, and
xTaskCounters are incremented from the individual event tasks - therefore
comparing xTaskCounters to xExpectedTaskCounters shows whether or not the
correct task was unblocked by the post. */
/* Each time the controlling task posts onto the queue it increments the
* expected count of the task that it expected to read the data from the queue
* (i.e. the task with the highest priority that should be blocked on the queue).
*
* xExpectedTaskCounters are incremented from the controlling task, and
* xTaskCounters are incremented from the individual event tasks - therefore
* comparing xTaskCounters to xExpectedTaskCounters shows whether or not the
* correct task was unblocked by the post. */
static portBASE_TYPE xExpectedTaskCounters[ evtNUM_TASKS ] = { 0, 0, 0, 0 };
/* Handles to the four event tasks. These are required to suspend and resume
the tasks. */
* the tasks. */
static TaskHandle_t xCreatedTasks[ evtNUM_TASKS ];
/* The single queue onto which the controlling task posts, and the four event
tasks block. */
* tasks block. */
static QueueHandle_t xQueue;
/* Flag used to indicate whether or not an error has occurred at any time.
An error is either the queue being full when not expected, or an unexpected
task reading data from the queue. */
* An error is either the queue being full when not expected, or an unexpected
* task reading data from the queue. */
static portBASE_TYPE xHealthStatus = pdPASS;
/*-----------------------------------------------------------*/
/* Function that implements the event task. This is created four times. */
static void prvMultiEventTask( void *pvParameters );
static void prvMultiEventTask( void * pvParameters );
/* Function that implements the controlling task. */
static void prvEventControllerTask( void *pvParameters );
static void prvEventControllerTask( void * pvParameters );
/* This is a utility function that posts data to the queue, then compares
xExpectedTaskCounters with xTaskCounters to ensure everything worked as
expected.
The event tasks all have higher priorities the controlling task. Therefore
the controlling task will always get preempted between writhing to the queue
and checking the task counters.
@param xExpectedTask The index to the task that the controlling task thinks
should be the highest priority task waiting for data, and
therefore the task that will unblock.
@param xIncrement The number of items that should be written to the queue.
*/
static void prvCheckTaskCounters( portBASE_TYPE xExpectedTask, portBASE_TYPE xIncrement );
/* This is a utility function that posts data to the queue, then compares
* xExpectedTaskCounters with xTaskCounters to ensure everything worked as
* expected.
*
* The event tasks all have higher priorities the controlling task. Therefore
* the controlling task will always get preempted between writhing to the queue
* and checking the task counters.
*
* @param xExpectedTask The index to the task that the controlling task thinks
* should be the highest priority task waiting for data, and
* therefore the task that will unblock.
*
* @param xIncrement The number of items that should be written to the queue.
*/
static void prvCheckTaskCounters( portBASE_TYPE xExpectedTask,
portBASE_TYPE xIncrement );
/* This is just incremented each cycle of the controlling tasks function so
the main application can ensure the test is still running. */
* the main application can ensure the test is still running. */
static portBASE_TYPE xCheckVariable = 0;
/*-----------------------------------------------------------*/
void vStartMultiEventTasks( void )
{
/* Create the queue to be used for all the communications. */
xQueue = xQueueCreate( evtQUEUE_LENGTH, ( unsigned portBASE_TYPE ) sizeof( unsigned portBASE_TYPE ) );
/* Create the queue to be used for all the communications. */
xQueue = xQueueCreate( evtQUEUE_LENGTH, ( unsigned portBASE_TYPE ) sizeof( unsigned portBASE_TYPE ) );
/* Start the controlling task. This has the idle priority to ensure it is
always preempted by the event tasks. */
xTaskCreate( prvEventControllerTask, "EvntCTRL", evtSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
/* Start the controlling task. This has the idle priority to ensure it is
* always preempted by the event tasks. */
xTaskCreate( prvEventControllerTask, "EvntCTRL", evtSTACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
/* Start the four event tasks. Note that two have priority 3, one
priority 2 and the other priority 1. */
xTaskCreate( prvMultiEventTask, "Event0", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 0 ] ), 1, &( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] ) );
xTaskCreate( prvMultiEventTask, "Event1", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 1 ] ), 2, &( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] ) );
xTaskCreate( prvMultiEventTask, "Event2", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 2 ] ), 3, &( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] ) );
xTaskCreate( prvMultiEventTask, "Event3", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 3 ] ), 3, &( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] ) );
/* Start the four event tasks. Note that two have priority 3, one
* priority 2 and the other priority 1. */
xTaskCreate( prvMultiEventTask, "Event0", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 0 ] ), 1, &( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] ) );
xTaskCreate( prvMultiEventTask, "Event1", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 1 ] ), 2, &( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] ) );
xTaskCreate( prvMultiEventTask, "Event2", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 2 ] ), 3, &( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] ) );
xTaskCreate( prvMultiEventTask, "Event3", evtSTACK_SIZE, ( void * ) &( xTaskCounters[ 3 ] ), 3, &( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] ) );
}
/*-----------------------------------------------------------*/
static void prvMultiEventTask( void *pvParameters )
static void prvMultiEventTask( void * pvParameters )
{
portBASE_TYPE *pxCounter;
unsigned portBASE_TYPE uxDummy;
const char * const pcTaskStartMsg = "Multi event task started.\r\n";
portBASE_TYPE * pxCounter;
unsigned portBASE_TYPE uxDummy;
const char * const pcTaskStartMsg = "Multi event task started.\r\n";
/* The variable this task will increment is passed in as a parameter. */
pxCounter = ( portBASE_TYPE * ) pvParameters;
/* The variable this task will increment is passed in as a parameter. */
pxCounter = ( portBASE_TYPE * ) pvParameters;
vPrintDisplayMessage( &pcTaskStartMsg );
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* Block on the queue. */
if( xQueueReceive( xQueue, &uxDummy, portMAX_DELAY ) )
{
/* We unblocked by reading the queue - so simply increment
the counter specific to this task instance. */
( *pxCounter )++;
}
else
{
xHealthStatus = pdFAIL;
}
}
for( ; ; )
{
/* Block on the queue. */
if( xQueueReceive( xQueue, &uxDummy, portMAX_DELAY ) )
{
/* We unblocked by reading the queue - so simply increment
* the counter specific to this task instance. */
( *pxCounter )++;
}
else
{
xHealthStatus = pdFAIL;
}
}
}
/*-----------------------------------------------------------*/
static void prvEventControllerTask( void *pvParameters )
static void prvEventControllerTask( void * pvParameters )
{
const char * const pcTaskStartMsg = "Multi event controller task started.\r\n";
portBASE_TYPE xDummy = 0;
const char * const pcTaskStartMsg = "Multi event controller task started.\r\n";
portBASE_TYPE xDummy = 0;
/* Just to stop warnings. */
( void ) pvParameters;
/* Just to stop warnings. */
( void ) pvParameters;
vPrintDisplayMessage( &pcTaskStartMsg );
vPrintDisplayMessage( &pcTaskStartMsg );
for( ;; )
{
/* All tasks are blocked on the queue. When a message is posted one of
the two tasks that share the highest priority should unblock to read
the queue. The next message written should unblock the other task with
the same high priority, and so on in order. No other task should
unblock to read data as they have lower priorities. */
for( ; ; )
{
/* All tasks are blocked on the queue. When a message is posted one of
* the two tasks that share the highest priority should unblock to read
* the queue. The next message written should unblock the other task with
* the same high priority, and so on in order. No other task should
* unblock to read data as they have lower priorities. */
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_2, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_2, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_2, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_2, 1 );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
/* For the rest of these tests we don't need the second 'highest'
priority task - so it is suspended. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] );
/* For the rest of these tests we don't need the second 'highest'
* priority task - so it is suspended. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] );
/* Now suspend the other highest priority task. The medium priority
task will then be the task with the highest priority that remains
blocked on the queue. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
/* This time, when we post onto the queue we will expect the medium
priority task to unblock and preempt us. */
prvCheckTaskCounters( evtMEDIUM_PRIORITY_INDEX, 1 );
/* Now suspend the other highest priority task. The medium priority
* task will then be the task with the highest priority that remains
* blocked on the queue. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
/* Now try resuming the highest priority task while the scheduler is
suspended. The task should start executing as soon as the scheduler
is resumed - therefore when we post to the queue again, the highest
priority task should again preempt us. */
vTaskSuspendAll();
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
xTaskResumeAll();
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
/* Now we are going to suspend the high and medium priority tasks. The
low priority task should then preempt us. Again the task suspension is
done with the whole scheduler suspended just for test purposes. */
vTaskSuspendAll();
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
vTaskSuspend( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
xTaskResumeAll();
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, 1 );
/* Do the same basic test another few times - selectively suspending
and resuming tasks and each time calling prvCheckTaskCounters() passing
to the function the number of the task we expected to be unblocked by
the post. */
/* This time, when we post onto the queue we will expect the medium
* priority task to unblock and preempt us. */
prvCheckTaskCounters( evtMEDIUM_PRIORITY_INDEX, 1 );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
vTaskSuspendAll(); /* Just for test. */
vTaskSuspendAll(); /* Just for test. */
vTaskSuspendAll(); /* Just for even more test. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
xTaskResumeAll();
xTaskResumeAll();
xTaskResumeAll();
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, 1 );
vTaskResume( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
prvCheckTaskCounters( evtMEDIUM_PRIORITY_INDEX, 1 );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
/* Now try resuming the highest priority task while the scheduler is
* suspended. The task should start executing as soon as the scheduler
* is resumed - therefore when we post to the queue again, the highest
* priority task should again preempt us. */
vTaskSuspendAll();
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
xTaskResumeAll();
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
/* Now a slight change, first suspend all tasks. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
vTaskSuspend( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
vTaskSuspend( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
/* Now when we resume the low priority task and write to the queue 3
times. We expect the low priority task to service the queue three
times. */
vTaskResume( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, evtQUEUE_LENGTH );
/* Again suspend all tasks (only the low priority task is not suspended
already). */
vTaskSuspend( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
/* This time we are going to suspend the scheduler, resume the low
priority task, then resume the high priority task. In this state we
will write to the queue three times. When the scheduler is resumed
we expect the high priority task to service all three messages. */
vTaskSuspendAll();
{
vTaskResume( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
for( xDummy = 0; xDummy < evtQUEUE_LENGTH; xDummy++ )
{
if( xQueueSend( xQueue, &xDummy, evtNO_DELAY ) != pdTRUE )
{
xHealthStatus = pdFAIL;
}
}
/* The queue should not have been serviced yet!. The scheduler
is still suspended. */
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
xHealthStatus = pdFAIL;
}
}
xTaskResumeAll();
/* Now we are going to suspend the high and medium priority tasks. The
* low priority task should then preempt us. Again the task suspension is
* done with the whole scheduler suspended just for test purposes. */
vTaskSuspendAll();
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
vTaskSuspend( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
xTaskResumeAll();
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, 1 );
/* We should have been preempted by resuming the scheduler - so by the
time we are running again we expect the high priority task to have
removed three items from the queue. */
xExpectedTaskCounters[ evtHIGHEST_PRIORITY_INDEX_1 ] += evtQUEUE_LENGTH;
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
xHealthStatus = pdFAIL;
}
/* The medium priority and second high priority tasks are still
suspended. Make sure to resume them before starting again. */
vTaskResume( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] );
/* Do the same basic test another few times - selectively suspending
* and resuming tasks and each time calling prvCheckTaskCounters() passing
* to the function the number of the task we expected to be unblocked by
* the post. */
/* Just keep incrementing to show the task is still executing. */
xCheckVariable++;
}
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
vTaskSuspendAll(); /* Just for test. */
vTaskSuspendAll(); /* Just for test. */
vTaskSuspendAll(); /* Just for even more test. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
xTaskResumeAll();
xTaskResumeAll();
xTaskResumeAll();
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, 1 );
vTaskResume( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
prvCheckTaskCounters( evtMEDIUM_PRIORITY_INDEX, 1 );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
prvCheckTaskCounters( evtHIGHEST_PRIORITY_INDEX_1, 1 );
/* Now a slight change, first suspend all tasks. */
vTaskSuspend( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
vTaskSuspend( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
vTaskSuspend( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
/* Now when we resume the low priority task and write to the queue 3
* times. We expect the low priority task to service the queue three
* times. */
vTaskResume( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
prvCheckTaskCounters( evtLOWEST_PRIORITY_INDEX, evtQUEUE_LENGTH );
/* Again suspend all tasks (only the low priority task is not suspended
* already). */
vTaskSuspend( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
/* This time we are going to suspend the scheduler, resume the low
* priority task, then resume the high priority task. In this state we
* will write to the queue three times. When the scheduler is resumed
* we expect the high priority task to service all three messages. */
vTaskSuspendAll();
{
vTaskResume( xCreatedTasks[ evtLOWEST_PRIORITY_INDEX ] );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_1 ] );
for( xDummy = 0; xDummy < evtQUEUE_LENGTH; xDummy++ )
{
if( xQueueSend( xQueue, &xDummy, evtNO_DELAY ) != pdTRUE )
{
xHealthStatus = pdFAIL;
}
}
/* The queue should not have been serviced yet!. The scheduler
* is still suspended. */
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
xHealthStatus = pdFAIL;
}
}
xTaskResumeAll();
/* We should have been preempted by resuming the scheduler - so by the
* time we are running again we expect the high priority task to have
* removed three items from the queue. */
xExpectedTaskCounters[ evtHIGHEST_PRIORITY_INDEX_1 ] += evtQUEUE_LENGTH;
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
xHealthStatus = pdFAIL;
}
/* The medium priority and second high priority tasks are still
* suspended. Make sure to resume them before starting again. */
vTaskResume( xCreatedTasks[ evtMEDIUM_PRIORITY_INDEX ] );
vTaskResume( xCreatedTasks[ evtHIGHEST_PRIORITY_INDEX_2 ] );
/* Just keep incrementing to show the task is still executing. */
xCheckVariable++;
}
}
/*-----------------------------------------------------------*/
static void prvCheckTaskCounters( portBASE_TYPE xExpectedTask, portBASE_TYPE xIncrement )
static void prvCheckTaskCounters( portBASE_TYPE xExpectedTask,
portBASE_TYPE xIncrement )
{
portBASE_TYPE xDummy = 0;
portBASE_TYPE xDummy = 0;
/* Write to the queue the requested number of times. The data written is
not important. */
for( xDummy = 0; xDummy < xIncrement; xDummy++ )
{
if( xQueueSend( xQueue, &xDummy, evtNO_DELAY ) != pdTRUE )
{
/* Did not expect to ever find the queue full. */
xHealthStatus = pdFAIL;
}
}
/* Write to the queue the requested number of times. The data written is
* not important. */
for( xDummy = 0; xDummy < xIncrement; xDummy++ )
{
if( xQueueSend( xQueue, &xDummy, evtNO_DELAY ) != pdTRUE )
{
/* Did not expect to ever find the queue full. */
xHealthStatus = pdFAIL;
}
}
/* All the tasks blocked on the queue have a priority higher than the
controlling task. Writing to the queue will therefore have caused this
task to be preempted. By the time this line executes the event task will
have executed and incremented its counter. Increment the expected counter
to the same value. */
( xExpectedTaskCounters[ xExpectedTask ] ) += xIncrement;
/* All the tasks blocked on the queue have a priority higher than the
* controlling task. Writing to the queue will therefore have caused this
* task to be preempted. By the time this line executes the event task will
* have executed and incremented its counter. Increment the expected counter
* to the same value. */
( xExpectedTaskCounters[ xExpectedTask ] ) += xIncrement;
/* Check the actual counts and expected counts really are the same. */
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
/* The counters were not the same. This means a task we did not expect
to unblock actually did unblock. */
xHealthStatus = pdFAIL;
}
/* Check the actual counts and expected counts really are the same. */
if( memcmp( ( void * ) xExpectedTaskCounters, ( void * ) xTaskCounters, sizeof( xExpectedTaskCounters ) ) )
{
/* The counters were not the same. This means a task we did not expect
* to unblock actually did unblock. */
xHealthStatus = pdFAIL;
}
}
/*-----------------------------------------------------------*/
portBASE_TYPE xAreMultiEventTasksStillRunning( void )
{
static portBASE_TYPE xPreviousCheckVariable = 0;
static portBASE_TYPE xPreviousCheckVariable = 0;
/* Called externally to periodically check that this test is still
operational. */
/* Called externally to periodically check that this test is still
* operational. */
if( xPreviousCheckVariable == xCheckVariable )
{
xHealthStatus = pdFAIL;
}
xPreviousCheckVariable = xCheckVariable;
return xHealthStatus;
if( xPreviousCheckVariable == xCheckVariable )
{
xHealthStatus = pdFAIL;
}
xPreviousCheckVariable = xCheckVariable;
return xHealthStatus;
}

99
FreeRTOS/Demo/Common/Full/flash.c
View file

@ -27,13 +27,13 @@
/**
* Creates eight tasks, each of which flash an LED at a different rate. The first
* Creates eight tasks, each of which flash an LED at a different rate. The first
* LED flashes every 125ms, the second every 250ms, the third every 375ms, etc.
*
* The LED flash tasks provide instant visual feedback. They show that the scheduler
* The LED flash tasks provide instant visual feedback. They show that the scheduler
* is still operational.
*
* The PC port uses the standard parallel port for outputs, the Flashlite 186 port
* The PC port uses the standard parallel port for outputs, the Flashlite 186 port
* uses IO port F.
*
* \page flashC flash.c
@ -42,16 +42,16 @@
*/
/*
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
Changes from V2.1.1
+ The stack size now uses configMINIMAL_STACK_SIZE.
+ String constants made file scope to decrease stack depth on 8051 port.
*/
* Changes from V2.0.0
*
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
+
+ Changes from V2.1.1
+
+ The stack size now uses configMINIMAL_STACK_SIZE.
+ String constants made file scope to decrease stack depth on 8051 port.
*/
#include <stdlib.h>
@ -64,18 +64,18 @@ Changes from V2.1.1
#include "flash.h"
#include "print.h"
#define ledSTACK_SIZE configMINIMAL_STACK_SIZE
#define ledSTACK_SIZE configMINIMAL_STACK_SIZE
/* Structure used to pass parameters to the LED tasks. */
typedef struct LED_PARAMETERS
{
unsigned portBASE_TYPE uxLED; /*< The output the task should use. */
TickType_t xFlashRate; /*< The rate at which the LED should flash. */
unsigned portBASE_TYPE uxLED; /*< The output the task should use. */
TickType_t xFlashRate; /*< The rate at which the LED should flash. */
} xLEDParameters;
/* The task that is created eight times - each time with a different xLEDParaemtes
structure passed in as the parameter. */
static void vLEDFlashTask( void *pvParameters );
/* The task that is created eight times - each time with a different xLEDParaemtes
* structure passed in as the parameter. */
static void vLEDFlashTask( void * pvParameters );
/* String to print if USE_STDIO is defined. */
const char * const pcTaskStartMsg = "LED flash task started.\r\n";
@ -84,45 +84,44 @@ const char * const pcTaskStartMsg = "LED flash task started.\r\n";
void vStartLEDFlashTasks( unsigned portBASE_TYPE uxPriority )
{
unsigned portBASE_TYPE uxLEDTask;
xLEDParameters *pxLEDParameters;
const unsigned portBASE_TYPE uxNumOfLEDs = 8;
const TickType_t xFlashRate = 125;
unsigned portBASE_TYPE uxLEDTask;
xLEDParameters * pxLEDParameters;
const unsigned portBASE_TYPE uxNumOfLEDs = 8;
const TickType_t xFlashRate = 125;
/* Create the eight tasks. */
for( uxLEDTask = 0; uxLEDTask < uxNumOfLEDs; ++uxLEDTask )
{
/* Create and complete the structure used to pass parameters to the next
created task. */
pxLEDParameters = ( xLEDParameters * ) pvPortMalloc( sizeof( xLEDParameters ) );
pxLEDParameters->uxLED = uxLEDTask;
pxLEDParameters->xFlashRate = ( xFlashRate + ( xFlashRate * ( TickType_t ) uxLEDTask ) );
pxLEDParameters->xFlashRate /= portTICK_PERIOD_MS;
/* Create the eight tasks. */
for( uxLEDTask = 0; uxLEDTask < uxNumOfLEDs; ++uxLEDTask )
{
/* Create and complete the structure used to pass parameters to the next
* created task. */
pxLEDParameters = ( xLEDParameters * ) pvPortMalloc( sizeof( xLEDParameters ) );
pxLEDParameters->uxLED = uxLEDTask;
pxLEDParameters->xFlashRate = ( xFlashRate + ( xFlashRate * ( TickType_t ) uxLEDTask ) );
pxLEDParameters->xFlashRate /= portTICK_PERIOD_MS;
/* Spawn the task. */
xTaskCreate( vLEDFlashTask, "LEDx", ledSTACK_SIZE, ( void * ) pxLEDParameters, uxPriority, ( TaskHandle_t * ) NULL );
}
/* Spawn the task. */
xTaskCreate( vLEDFlashTask, "LEDx", ledSTACK_SIZE, ( void * ) pxLEDParameters, uxPriority, ( TaskHandle_t * ) NULL );
}
}
/*-----------------------------------------------------------*/
static void vLEDFlashTask( void *pvParameters )
static void vLEDFlashTask( void * pvParameters )
{
xLEDParameters *pxParameters;
xLEDParameters * pxParameters;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
pxParameters = ( xLEDParameters * ) pvParameters;
pxParameters = ( xLEDParameters * ) pvParameters;
for(;;)
{
/* Delay for half the flash period then turn the LED on. */
vTaskDelay( pxParameters->xFlashRate / ( TickType_t ) 2 );
vParTestToggleLED( pxParameters->uxLED );
for( ; ; )
{
/* Delay for half the flash period then turn the LED on. */
vTaskDelay( pxParameters->xFlashRate / ( TickType_t ) 2 );
vParTestToggleLED( pxParameters->uxLED );
/* Delay for half the flash period then turn the LED off. */
vTaskDelay( pxParameters->xFlashRate / ( TickType_t ) 2 );
vParTestToggleLED( pxParameters->uxLED );
}
/* Delay for half the flash period then turn the LED off. */
vTaskDelay( pxParameters->xFlashRate / ( TickType_t ) 2 );
vParTestToggleLED( pxParameters->uxLED );
}
}

421
FreeRTOS/Demo/Common/Full/flop.c
View file

@ -26,22 +26,22 @@
*/
/*
Changes from V1.2.3
+ The created tasks now include calls to tskYIELD(), allowing them to be used
with the cooperative scheduler.
*/
* Changes from V1.2.3
*
+ The created tasks now include calls to tskYIELD(), allowing them to be used
+ with the cooperative scheduler.
*/
/**
* Creates eight tasks, each of which loops continuously performing an (emulated)
* Creates eight tasks, each of which loops continuously performing an (emulated)
* floating point calculation.
*
* All the tasks run at the idle priority and never block or yield. This causes
* all eight tasks to time slice with the idle task. Running at the idle priority
* All the tasks run at the idle priority and never block or yield. This causes
* all eight tasks to time slice with the idle task. Running at the idle priority
* means that these tasks will get pre-empted any time another task is ready to run
* or a time slice occurs. More often than not the pre-emption will occur mid
* calculation, creating a good test of the schedulers context switch mechanism - a
* calculation producing an unexpected result could be a symptom of a corruption in
* or a time slice occurs. More often than not the pre-emption will occur mid
* calculation, creating a good test of the schedulers context switch mechanism - a
* calculation producing an unexpected result could be a symptom of a corruption in
* the context of a task.
*
* \page FlopC flop.c
@ -60,272 +60,271 @@ Changes from V1.2.3
/* Demo program include files. */
#include "flop.h"
#define mathSTACK_SIZE ( ( unsigned short ) 512 )
#define mathNUMBER_OF_TASKS ( 8 )
#define mathSTACK_SIZE ( ( unsigned short ) 512 )
#define mathNUMBER_OF_TASKS ( 8 )
/* Four tasks, each of which performs a different floating point calculation.
Each of the four is created twice. */
static void vCompetingMathTask1( void *pvParameters );
static void vCompetingMathTask2( void *pvParameters );
static void vCompetingMathTask3( void *pvParameters );
static void vCompetingMathTask4( void *pvParameters );
/* Four tasks, each of which performs a different floating point calculation.
* Each of the four is created twice. */
static void vCompetingMathTask1( void * pvParameters );
static void vCompetingMathTask2( void * pvParameters );
static void vCompetingMathTask3( void * pvParameters );
static void vCompetingMathTask4( void * pvParameters );
/* These variables are used to check that all the tasks are still running. If a
task gets a calculation wrong it will
stop incrementing its check variable. */
/* These variables are used to check that all the tasks are still running. If a
* task gets a calculation wrong it will
* stop incrementing its check variable. */
static volatile unsigned short usTaskCheck[ mathNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
/*-----------------------------------------------------------*/
void vStartMathTasks( unsigned portBASE_TYPE uxPriority )
{
xTaskCreate( vCompetingMathTask1, "Math1", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 0 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask2, "Math2", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 1 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask3, "Math3", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 2 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask4, "Math4", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 3 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask1, "Math5", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 4 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask2, "Math6", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 5 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask3, "Math7", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 6 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask4, "Math8", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 7 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask1, "Math1", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 0 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask2, "Math2", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 1 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask3, "Math3", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 2 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask4, "Math4", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 3 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask1, "Math5", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 4 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask2, "Math6", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 5 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask3, "Math7", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 6 ] ), uxPriority, NULL );
xTaskCreate( vCompetingMathTask4, "Math8", mathSTACK_SIZE, ( void * ) &( usTaskCheck[ 7 ] ), uxPriority, NULL );
}
/*-----------------------------------------------------------*/
static void vCompetingMathTask1( void *pvParameters )
static void vCompetingMathTask1( void * pvParameters )
{
portDOUBLE d1, d2, d3, d4;
volatile unsigned short *pusTaskCheckVariable;
const portDOUBLE dAnswer = ( 123.4567 + 2345.6789 ) * -918.222;
const char * const pcTaskStartMsg = "Math task 1 started.\r\n";
const char * const pcTaskFailMsg = "Math task 1 failed.\r\n";
short sError = pdFALSE;
portDOUBLE d1, d2, d3, d4;
volatile unsigned short * pusTaskCheckVariable;
const portDOUBLE dAnswer = ( 123.4567 + 2345.6789 ) * -918.222;
const char * const pcTaskStartMsg = "Math task 1 started.\r\n";
const char * const pcTaskFailMsg = "Math task 1 failed.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Keep performing a calculation and checking the result against a constant. */
for(;;)
{
d1 = 123.4567;
d2 = 2345.6789;
d3 = -918.222;
/* Keep performing a calculation and checking the result against a constant. */
for( ; ; )
{
d1 = 123.4567;
d2 = 2345.6789;
d3 = -918.222;
d4 = ( d1 + d2 ) * d3;
d4 = ( d1 + d2 ) * d3;
taskYIELD();
taskYIELD();
/* If the calculation does not match the expected constant, stop the
increment of the check variable. */
if( fabs( d4 - dAnswer ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
/* If the calculation does not match the expected constant, stop the
* increment of the check variable. */
if( fabs( d4 - dAnswer ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
taskYIELD();
}
taskYIELD();
}
}
/*-----------------------------------------------------------*/
static void vCompetingMathTask2( void *pvParameters )
static void vCompetingMathTask2( void * pvParameters )
{
portDOUBLE d1, d2, d3, d4;
volatile unsigned short *pusTaskCheckVariable;
const portDOUBLE dAnswer = ( -389.38 / 32498.2 ) * -2.0001;
const char * const pcTaskStartMsg = "Math task 2 started.\r\n";
const char * const pcTaskFailMsg = "Math task 2 failed.\r\n";
short sError = pdFALSE;
portDOUBLE d1, d2, d3, d4;
volatile unsigned short * pusTaskCheckVariable;
const portDOUBLE dAnswer = ( -389.38 / 32498.2 ) * -2.0001;
const char * const pcTaskStartMsg = "Math task 2 started.\r\n";
const char * const pcTaskFailMsg = "Math task 2 failed.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Keep performing a calculation and checking the result against a constant. */
for( ;; )
{
d1 = -389.38;
d2 = 32498.2;
d3 = -2.0001;
/* Keep performing a calculation and checking the result against a constant. */
for( ; ; )
{
d1 = -389.38;
d2 = 32498.2;
d3 = -2.0001;
d4 = ( d1 / d2 ) * d3;
d4 = ( d1 / d2 ) * d3;
taskYIELD();
/* If the calculation does not match the expected constant, stop the
increment of the check variable. */
if( fabs( d4 - dAnswer ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
taskYIELD();
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know
this task is still running okay. */
( *pusTaskCheckVariable )++;
}
/* If the calculation does not match the expected constant, stop the
* increment of the check variable. */
if( fabs( d4 - dAnswer ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
taskYIELD();
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know
* this task is still running okay. */
( *pusTaskCheckVariable )++;
}
taskYIELD();
}
}
/*-----------------------------------------------------------*/
static void vCompetingMathTask3( void *pvParameters )
static void vCompetingMathTask3( void * pvParameters )
{
portDOUBLE *pdArray, dTotal1, dTotal2, dDifference;
volatile unsigned short *pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Math task 3 started.\r\n";
const char * const pcTaskFailMsg = "Math task 3 failed.\r\n";
short sError = pdFALSE;
portDOUBLE * pdArray, dTotal1, dTotal2, dDifference;
volatile unsigned short * pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Math task 3 started.\r\n";
const char * const pcTaskFailMsg = "Math task 3 failed.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
pdArray = ( portDOUBLE * ) pvPortMalloc( ( size_t ) 250 * sizeof( portDOUBLE ) );
pdArray = ( portDOUBLE * ) pvPortMalloc( ( size_t ) 250 * sizeof( portDOUBLE ) );
/* Keep filling an array, keeping a running total of the values placed in the
array. Then run through the array adding up all the values. If the two totals
do not match, stop the check variable from incrementing. */
for( ;; )
{
dTotal1 = 0.0;
dTotal2 = 0.0;
/* Keep filling an array, keeping a running total of the values placed in the
* array. Then run through the array adding up all the values. If the two totals
* do not match, stop the check variable from incrementing. */
for( ; ; )
{
dTotal1 = 0.0;
dTotal2 = 0.0;
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
pdArray[ usPosition ] = ( portDOUBLE ) usPosition + 5.5;
dTotal1 += ( portDOUBLE ) usPosition + 5.5;
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
pdArray[ usPosition ] = ( portDOUBLE ) usPosition + 5.5;
dTotal1 += ( portDOUBLE ) usPosition + 5.5;
}
taskYIELD();
taskYIELD();
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
dTotal2 += pdArray[ usPosition ];
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
dTotal2 += pdArray[ usPosition ];
}
dDifference = dTotal1 - dTotal2;
if( fabs( dDifference ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
dDifference = dTotal1 - dTotal2;
taskYIELD();
if( fabs( dDifference ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
taskYIELD();
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
static void vCompetingMathTask4( void *pvParameters )
static void vCompetingMathTask4( void * pvParameters )
{
portDOUBLE *pdArray, dTotal1, dTotal2, dDifference;
volatile unsigned short *pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Math task 4 started.\r\n";
const char * const pcTaskFailMsg = "Math task 4 failed.\r\n";
short sError = pdFALSE;
portDOUBLE * pdArray, dTotal1, dTotal2, dDifference;
volatile unsigned short * pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Math task 4 started.\r\n";
const char * const pcTaskFailMsg = "Math task 4 failed.\r\n";
short sError = pdFALSE;
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
pdArray = ( portDOUBLE * ) pvPortMalloc( ( size_t ) 250 * sizeof( portDOUBLE ) );
pdArray = ( portDOUBLE * ) pvPortMalloc( ( size_t ) 250 * sizeof( portDOUBLE ) );
/* Keep filling an array, keeping a running total of the values placed in the
array. Then run through the array adding up all the values. If the two totals
do not match, stop the check variable from incrementing. */
for( ;; )
{
dTotal1 = 0.0;
dTotal2 = 0.0;
/* Keep filling an array, keeping a running total of the values placed in the
* array. Then run through the array adding up all the values. If the two totals
* do not match, stop the check variable from incrementing. */
for( ; ; )
{
dTotal1 = 0.0;
dTotal2 = 0.0;
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
pdArray[ usPosition ] = ( portDOUBLE ) usPosition * 12.123;
dTotal1 += ( portDOUBLE ) usPosition * 12.123;
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
pdArray[ usPosition ] = ( portDOUBLE ) usPosition * 12.123;
dTotal1 += ( portDOUBLE ) usPosition * 12.123;
}
taskYIELD();
taskYIELD();
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
dTotal2 += pdArray[ usPosition ];
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
dTotal2 += pdArray[ usPosition ];
}
dDifference = dTotal1 - dTotal2;
if( fabs( dDifference ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
dDifference = dTotal1 - dTotal2;
taskYIELD();
if( fabs( dDifference ) > 0.001 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
taskYIELD();
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running. */
portBASE_TYPE xAreMathsTaskStillRunning( void )
{
/* Keep a history of the check variables so we know if they have been incremented
since the last call. */
static unsigned short usLastTaskCheck[ mathNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
portBASE_TYPE xReturn = pdTRUE, xTask;
/* Keep a history of the check variables so we know if they have been incremented
* since the last call. */
static unsigned short usLastTaskCheck[ mathNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
portBASE_TYPE xReturn = pdTRUE, xTask;
/* Check the maths tasks are still running by ensuring their check variables
are still incrementing. */
for( xTask = 0; xTask < mathNUMBER_OF_TASKS; xTask++ )
{
if( usTaskCheck[ xTask ] == usLastTaskCheck[ xTask ] )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
/* Check the maths tasks are still running by ensuring their check variables
* are still incrementing. */
for( xTask = 0; xTask < mathNUMBER_OF_TASKS; xTask++ )
{
if( usTaskCheck[ xTask ] == usLastTaskCheck[ xTask ] )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
usLastTaskCheck[ xTask ] = usTaskCheck[ xTask ];
}
usLastTaskCheck[ xTask ] = usTaskCheck[ xTask ];
}
return xReturn;
return xReturn;
}

419
FreeRTOS/Demo/Common/Full/integer.c
View file

@ -26,21 +26,21 @@
*/
/*
Changes from V1.2.3
+ The created tasks now include calls to tskYIELD(), allowing them to be used
with the cooperative scheduler.
*/
* Changes from V1.2.3
*
+ The created tasks now include calls to tskYIELD(), allowing them to be used
+ with the cooperative scheduler.
*/
/**
* This does the same as flop. c, but uses variables of type long instead of
* type double.
* This does the same as flop. c, but uses variables of type long instead of
* type double.
*
* As with flop. c, the tasks created in this file are a good test of the
* scheduler context switch mechanism. The processor has to access 32bit
* variables in two or four chunks (depending on the processor). The low
* priority of these tasks means there is a high probability that a context
* switch will occur mid calculation. See the flop. c documentation for
* As with flop. c, the tasks created in this file are a good test of the
* scheduler context switch mechanism. The processor has to access 32bit
* variables in two or four chunks (depending on the processor). The low
* priority of these tasks means there is a high probability that a context
* switch will occur mid calculation. See the flop. c documentation for
* more information.
*
* \page IntegerC integer.c
@ -49,11 +49,11 @@ Changes from V1.2.3
*/
/*
Changes from V1.2.1
+ The constants used in the calculations are larger to ensure the
optimiser does not truncate them to 16 bits.
*/
* Changes from V1.2.1
*
+ The constants used in the calculations are larger to ensure the
+ optimiser does not truncate them to 16 bits.
*/
#include <stdlib.h>
@ -65,263 +65,262 @@ Changes from V1.2.1
/* Demo program include files. */
#include "integer.h"
#define intgSTACK_SIZE ( ( unsigned short ) 256 )
#define intgNUMBER_OF_TASKS ( 8 )
#define intgSTACK_SIZE ( ( unsigned short ) 256 )
#define intgNUMBER_OF_TASKS ( 8 )
/* Four tasks, each of which performs a different calculation on four byte
variables. Each of the four is created twice. */
static void vCompeteingIntMathTask1( void *pvParameters );
static void vCompeteingIntMathTask2( void *pvParameters );
static void vCompeteingIntMathTask3( void *pvParameters );
static void vCompeteingIntMathTask4( void *pvParameters );
/* Four tasks, each of which performs a different calculation on four byte
* variables. Each of the four is created twice. */
static void vCompeteingIntMathTask1( void * pvParameters );
static void vCompeteingIntMathTask2( void * pvParameters );
static void vCompeteingIntMathTask3( void * pvParameters );
static void vCompeteingIntMathTask4( void * pvParameters );
/* These variables are used to check that all the tasks are still running. If a
task gets a calculation wrong it will stop incrementing its check variable. */
/* These variables are used to check that all the tasks are still running. If a
* task gets a calculation wrong it will stop incrementing its check variable. */
static volatile unsigned short usTaskCheck[ intgNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
/*-----------------------------------------------------------*/
void vStartIntegerMathTasks( unsigned portBASE_TYPE uxPriority )
{
xTaskCreate( vCompeteingIntMathTask1, "IntMath1", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 0 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask2, "IntMath2", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 1 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask3, "IntMath3", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 2 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask4, "IntMath4", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 3 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask1, "IntMath5", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 4 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask2, "IntMath6", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 5 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask3, "IntMath7", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 6 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask4, "IntMath8", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 7 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask1, "IntMath1", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 0 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask2, "IntMath2", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 1 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask3, "IntMath3", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 2 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask4, "IntMath4", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 3 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask1, "IntMath5", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 4 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask2, "IntMath6", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 5 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask3, "IntMath7", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 6 ] ), uxPriority, NULL );
xTaskCreate( vCompeteingIntMathTask4, "IntMath8", intgSTACK_SIZE, ( void * ) &( usTaskCheck[ 7 ] ), uxPriority, NULL );
}
/*-----------------------------------------------------------*/
static void vCompeteingIntMathTask1( void *pvParameters )
static void vCompeteingIntMathTask1( void * pvParameters )
{
long l1, l2, l3, l4;
short sError = pdFALSE;
volatile unsigned short *pusTaskCheckVariable;
const long lAnswer = ( ( long ) 74565L + ( long ) 1234567L ) * ( long ) -918L;
const char * const pcTaskStartMsg = "Integer math task 1 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 1 failed.\r\n";
long l1, l2, l3, l4;
short sError = pdFALSE;
volatile unsigned short * pusTaskCheckVariable;
const long lAnswer = ( ( long ) 74565L + ( long ) 1234567L ) * ( long ) -918L;
const char * const pcTaskStartMsg = "Integer math task 1 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 1 failed.\r\n";
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Keep performing a calculation and checking the result against a constant. */
for(;;)
{
l1 = ( long ) 74565L;
l2 = ( long ) 1234567L;
l3 = ( long ) -918L;
/* Keep performing a calculation and checking the result against a constant. */
for( ; ; )
{
l1 = ( long ) 74565L;
l2 = ( long ) 1234567L;
l3 = ( long ) -918L;
l4 = ( l1 + l2 ) * l3;
l4 = ( l1 + l2 ) * l3;
taskYIELD();
taskYIELD();
/* If the calculation does not match the expected constant, stop the
increment of the check variable. */
if( l4 != lAnswer )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
/* If the calculation does not match the expected constant, stop the
* increment of the check variable. */
if( l4 != lAnswer )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
static void vCompeteingIntMathTask2( void *pvParameters )
static void vCompeteingIntMathTask2( void * pvParameters )
{
long l1, l2, l3, l4;
short sError = pdFALSE;
volatile unsigned short *pusTaskCheckVariable;
const long lAnswer = ( ( long ) -389000L / ( long ) 329999L ) * ( long ) -89L;
const char * const pcTaskStartMsg = "Integer math task 2 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 2 failed.\r\n";
long l1, l2, l3, l4;
short sError = pdFALSE;
volatile unsigned short * pusTaskCheckVariable;
const long lAnswer = ( ( long ) -389000L / ( long ) 329999L ) * ( long ) -89L;
const char * const pcTaskStartMsg = "Integer math task 2 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 2 failed.\r\n";
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Keep performing a calculation and checking the result against a constant. */
for( ;; )
{
l1 = -389000L;
l2 = 329999L;
l3 = -89L;
/* Keep performing a calculation and checking the result against a constant. */
for( ; ; )
{
l1 = -389000L;
l2 = 329999L;
l3 = -89L;
l4 = ( l1 / l2 ) * l3;
l4 = ( l1 / l2 ) * l3;
taskYIELD();
taskYIELD();
/* If the calculation does not match the expected constant, stop the
increment of the check variable. */
if( l4 != lAnswer )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
/* If the calculation does not match the expected constant, stop the
* increment of the check variable. */
if( l4 != lAnswer )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
static void vCompeteingIntMathTask3( void *pvParameters )
static void vCompeteingIntMathTask3( void * pvParameters )
{
long *plArray, lTotal1, lTotal2;
short sError = pdFALSE;
volatile unsigned short *pusTaskCheckVariable;
const unsigned short usArraySize = ( unsigned short ) 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Integer math task 3 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 3 failed.\r\n";
long * plArray, lTotal1, lTotal2;
short sError = pdFALSE;
volatile unsigned short * pusTaskCheckVariable;
const unsigned short usArraySize = ( unsigned short ) 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Integer math task 3 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 3 failed.\r\n";
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Create the array we are going to use for our check calculation. */
plArray = ( long * ) pvPortMalloc( ( size_t ) 250 * sizeof( long ) );
/* Create the array we are going to use for our check calculation. */
plArray = ( long * ) pvPortMalloc( ( size_t ) 250 * sizeof( long ) );
/* Keep filling the array, keeping a running total of the values placed in the
array. Then run through the array adding up all the values. If the two totals
do not match, stop the check variable from incrementing. */
for( ;; )
{
lTotal1 = ( long ) 0;
lTotal2 = ( long ) 0;
/* Keep filling the array, keeping a running total of the values placed in the
* array. Then run through the array adding up all the values. If the two totals
* do not match, stop the check variable from incrementing. */
for( ; ; )
{
lTotal1 = ( long ) 0;
lTotal2 = ( long ) 0;
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
plArray[ usPosition ] = ( long ) usPosition + ( long ) 5;
lTotal1 += ( long ) usPosition + ( long ) 5;
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
plArray[ usPosition ] = ( long ) usPosition + ( long ) 5;
lTotal1 += ( long ) usPosition + ( long ) 5;
}
taskYIELD();
taskYIELD();
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
lTotal2 += plArray[ usPosition ];
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
lTotal2 += plArray[ usPosition ];
}
if( lTotal1 != lTotal2 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( lTotal1 != lTotal2 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
taskYIELD();
taskYIELD();
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
static void vCompeteingIntMathTask4( void *pvParameters )
static void vCompeteingIntMathTask4( void * pvParameters )
{
long *plArray, lTotal1, lTotal2;
short sError = pdFALSE;
volatile unsigned short *pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Integer math task 4 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 4 failed.\r\n";
long * plArray, lTotal1, lTotal2;
short sError = pdFALSE;
volatile unsigned short * pusTaskCheckVariable;
const unsigned short usArraySize = 250;
unsigned short usPosition;
const char * const pcTaskStartMsg = "Integer math task 4 started.\r\n";
const char * const pcTaskFailMsg = "Integer math task 4 failed.\r\n";
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcTaskStartMsg );
/* The variable this task increments to show it is still running is passed in
as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* The variable this task increments to show it is still running is passed in
* as the parameter. */
pusTaskCheckVariable = ( unsigned short * ) pvParameters;
/* Create the array we are going to use for our check calculation. */
plArray = ( long * ) pvPortMalloc( ( size_t ) 250 * sizeof( long ) );
/* Create the array we are going to use for our check calculation. */
plArray = ( long * ) pvPortMalloc( ( size_t ) 250 * sizeof( long ) );
/* Keep filling the array, keeping a running total of the values placed in the
array. Then run through the array adding up all the values. If the two totals
do not match, stop the check variable from incrementing. */
for( ;; )
{
lTotal1 = ( long ) 0;
lTotal2 = ( long ) 0;
/* Keep filling the array, keeping a running total of the values placed in the
* array. Then run through the array adding up all the values. If the two totals
* do not match, stop the check variable from incrementing. */
for( ; ; )
{
lTotal1 = ( long ) 0;
lTotal2 = ( long ) 0;
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
plArray[ usPosition ] = ( long ) usPosition * ( long ) 12;
lTotal1 += ( long ) usPosition * ( long ) 12;
}
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
plArray[ usPosition ] = ( long ) usPosition * ( long ) 12;
lTotal1 += ( long ) usPosition * ( long ) 12;
}
taskYIELD();
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
lTotal2 += plArray[ usPosition ];
}
taskYIELD();
for( usPosition = 0; usPosition < usArraySize; usPosition++ )
{
lTotal2 += plArray[ usPosition ];
}
if( lTotal1 != lTotal2 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
if( lTotal1 != lTotal2 )
{
vPrintDisplayMessage( &pcTaskFailMsg );
sError = pdTRUE;
}
taskYIELD();
taskYIELD();
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
if( sError == pdFALSE )
{
/* If the calculation has always been correct, increment the check
* variable so we know this task is still running okay. */
( *pusTaskCheckVariable )++;
}
}
}
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running. */
portBASE_TYPE xAreIntegerMathsTaskStillRunning( void )
{
/* Keep a history of the check variables so we know if they have been incremented
since the last call. */
static unsigned short usLastTaskCheck[ intgNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
portBASE_TYPE xReturn = pdTRUE, xTask;
/* Keep a history of the check variables so we know if they have been incremented
* since the last call. */
static unsigned short usLastTaskCheck[ intgNUMBER_OF_TASKS ] = { ( unsigned short ) 0 };
portBASE_TYPE xReturn = pdTRUE, xTask;
/* Check the maths tasks are still running by ensuring their check variables
are still incrementing. */
for( xTask = 0; xTask < intgNUMBER_OF_TASKS; xTask++ )
{
if( usTaskCheck[ xTask ] == usLastTaskCheck[ xTask ] )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
/* Check the maths tasks are still running by ensuring their check variables
* are still incrementing. */
for( xTask = 0; xTask < intgNUMBER_OF_TASKS; xTask++ )
{
if( usTaskCheck[ xTask ] == usLastTaskCheck[ xTask ] )
{
/* The check has not incremented so an error exists. */
xReturn = pdFALSE;
}
usLastTaskCheck[ xTask ] = usTaskCheck[ xTask ];
}
usLastTaskCheck[ xTask ] = usTaskCheck[ xTask ];
}
return xReturn;
return xReturn;
}

68
FreeRTOS/Demo/Common/Full/print.c
View file

@ -26,22 +26,22 @@
*/
/**
* Manages a queue of strings that are waiting to be displayed. This is used to
* Manages a queue of strings that are waiting to be displayed. This is used to
* ensure mutual exclusion of console output.
*
* A task wishing to display a message will call vPrintDisplayMessage (), with a
* pointer to the string as the parameter. The pointer is posted onto the
* A task wishing to display a message will call vPrintDisplayMessage (), with a
* pointer to the string as the parameter. The pointer is posted onto the
* xPrintQueue queue.
*
* The task spawned in main. c blocks on xPrintQueue. When a message becomes
* available it calls pcPrintGetNextMessage () to obtain a pointer to the next
* string, then uses the functions defined in the portable layer FileIO. c to
* The task spawned in main. c blocks on xPrintQueue. When a message becomes
* available it calls pcPrintGetNextMessage () to obtain a pointer to the next
* string, then uses the functions defined in the portable layer FileIO. c to
* display the message.
*
* <b>NOTE:</b>
* Using console IO can disrupt real time performance - depending on the port.
* Standard C IO routines are not designed for real time applications. While
* standard IO is useful for demonstration and debugging an alternative method
* Using console IO can disrupt real time performance - depending on the port.
* Standard C IO routines are not designed for real time applications. While
* standard IO is useful for demonstration and debugging an alternative method
* should be used if you actually require console IO as part of your application.
*
* \page PrintC print.c
@ -50,11 +50,11 @@
*/
/*
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
*/
* Changes from V2.0.0
*
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
*/
#include <stdlib.h>
@ -71,36 +71,34 @@ static QueueHandle_t xPrintQueue;
void vPrintInitialise( void )
{
const unsigned portBASE_TYPE uxQueueSize = 20;
const unsigned portBASE_TYPE uxQueueSize = 20;
/* Create the queue on which errors will be reported. */
xPrintQueue = xQueueCreate( uxQueueSize, ( unsigned portBASE_TYPE ) sizeof( char * ) );
/* Create the queue on which errors will be reported. */
xPrintQueue = xQueueCreate( uxQueueSize, ( unsigned portBASE_TYPE ) sizeof( char * ) );
}
/*-----------------------------------------------------------*/
void vPrintDisplayMessage( const char * const * ppcMessageToSend )
{
#ifdef USE_STDIO
xQueueSend( xPrintQueue, ( void * ) ppcMessageToSend, ( TickType_t ) 0 );
#else
/* Stop warnings. */
( void ) ppcMessageToSend;
#endif
#ifdef USE_STDIO
xQueueSend( xPrintQueue, ( void * ) ppcMessageToSend, ( TickType_t ) 0 );
#else
/* Stop warnings. */
( void ) ppcMessageToSend;
#endif
}
/*-----------------------------------------------------------*/
const char *pcPrintGetNextMessage( TickType_t xPrintRate )
const char * pcPrintGetNextMessage( TickType_t xPrintRate )
{
char *pcMessage;
char * pcMessage;
if( xQueueReceive( xPrintQueue, &pcMessage, xPrintRate ) == pdPASS )
{
return pcMessage;
}
else
{
return NULL;
}
if( xQueueReceive( xPrintQueue, &pcMessage, xPrintRate ) == pdPASS )
{
return pcMessage;
}
else
{
return NULL;
}
}

355
FreeRTOS/Demo/Common/Full/semtest.c
View file

@ -26,24 +26,24 @@
*/
/**
* Creates two sets of two tasks. The tasks within a set share a variable, access
* Creates two sets of two tasks. The tasks within a set share a variable, access
* to which is guarded by a semaphore.
*
* Each task starts by attempting to obtain the semaphore. On obtaining a
* semaphore a task checks to ensure that the guarded variable has an expected
* value. It then clears the variable to zero before counting it back up to the
* expected value in increments of 1. After each increment the variable is checked
* to ensure it contains the value to which it was just set. When the starting
* value is again reached the task releases the semaphore giving the other task in
* the set a chance to do exactly the same thing. The starting value is high
*
* Each task starts by attempting to obtain the semaphore. On obtaining a
* semaphore a task checks to ensure that the guarded variable has an expected
* value. It then clears the variable to zero before counting it back up to the
* expected value in increments of 1. After each increment the variable is checked
* to ensure it contains the value to which it was just set. When the starting
* value is again reached the task releases the semaphore giving the other task in
* the set a chance to do exactly the same thing. The starting value is high
* enough to ensure that a tick is likely to occur during the incrementing loop.
*
* An error is flagged if at any time during the process a shared variable is
* found to have a value other than that expected. Such an occurrence would
* suggest an error in the mutual exclusion mechanism by which access to the
* An error is flagged if at any time during the process a shared variable is
* found to have a value other than that expected. Such an occurrence would
* suggest an error in the mutual exclusion mechanism by which access to the
* variable is restricted.
*
* The first set of two tasks poll their semaphore. The second set use blocking
* The first set of two tasks poll their semaphore. The second set use blocking
* calls.
*
* \page SemTestC semtest.c
@ -52,24 +52,24 @@
*/
/*
Changes from V1.2.0:
+ The tasks that operate at the idle priority now use a lower expected
count than those running at a higher priority. This prevents the low
priority tasks from signaling an error because they have not been
scheduled enough time for each of them to count the shared variable to
the high value.
Changes from V2.0.0
+ Delay periods are now specified using variables and constants of
TickType_t rather than unsigned long.
Changes from V2.1.1
+ The stack size now uses configMINIMAL_STACK_SIZE.
+ String constants made file scope to decrease stack depth on 8051 port.
*/
* Changes from V1.2.0:
*
+ The tasks that operate at the idle priority now use a lower expected
+ count than those running at a higher priority. This prevents the low
+ priority tasks from signaling an error because they have not been
+ scheduled enough time for each of them to count the shared variable to
+ the high value.
+
+ Changes from V2.0.0
+
+ Delay periods are now specified using variables and constants of
+ TickType_t rather than unsigned long.
+
+ Changes from V2.1.1
+
+ The stack size now uses configMINIMAL_STACK_SIZE.
+ String constants made file scope to decrease stack depth on 8051 port.
*/
#include <stdlib.h>
@ -83,24 +83,24 @@ Changes from V2.1.1
#include "print.h"
/* The value to which the shared variables are counted. */
#define semtstBLOCKING_EXPECTED_VALUE ( ( unsigned long ) 0xfff )
#define semtstNON_BLOCKING_EXPECTED_VALUE ( ( unsigned long ) 0xff )
#define semtstBLOCKING_EXPECTED_VALUE ( ( unsigned long ) 0xfff )
#define semtstNON_BLOCKING_EXPECTED_VALUE ( ( unsigned long ) 0xff )
#define semtstSTACK_SIZE configMINIMAL_STACK_SIZE
#define semtstSTACK_SIZE configMINIMAL_STACK_SIZE
#define semtstNUM_TASKS ( 4 )
#define semtstNUM_TASKS ( 4 )
#define semtstDELAY_FACTOR ( ( TickType_t ) 10 )
#define semtstDELAY_FACTOR ( ( TickType_t ) 10 )
/* The task function as described at the top of the file. */
static void prvSemaphoreTest( void *pvParameters );
static void prvSemaphoreTest( void * pvParameters );
/* Structure used to pass parameters to each task. */
typedef struct SEMAPHORE_PARAMETERS
{
SemaphoreHandle_t xSemaphore;
volatile unsigned long *pulSharedVariable;
TickType_t xBlockTime;
SemaphoreHandle_t xSemaphore;
volatile unsigned long * pulSharedVariable;
TickType_t xBlockTime;
} xSemaphoreParameters;
/* Variables used to check that all the tasks are still running without errors. */
@ -115,171 +115,172 @@ const char * const pcSemaphoreTaskStart = "Guarded shared variable task started.
void vStartSemaphoreTasks( unsigned portBASE_TYPE uxPriority )
{
xSemaphoreParameters *pxFirstSemaphoreParameters, *pxSecondSemaphoreParameters;
const TickType_t xBlockTime = ( TickType_t ) 100;
xSemaphoreParameters * pxFirstSemaphoreParameters, * pxSecondSemaphoreParameters;
const TickType_t xBlockTime = ( TickType_t ) 100;
/* Create the structure used to pass parameters to the first two tasks. */
pxFirstSemaphoreParameters = ( xSemaphoreParameters * ) pvPortMalloc( sizeof( xSemaphoreParameters ) );
/* Create the structure used to pass parameters to the first two tasks. */
pxFirstSemaphoreParameters = ( xSemaphoreParameters * ) pvPortMalloc( sizeof( xSemaphoreParameters ) );
if( pxFirstSemaphoreParameters != NULL )
{
/* Create the semaphore used by the first two tasks. */
vSemaphoreCreateBinary( pxFirstSemaphoreParameters->xSemaphore );
if( pxFirstSemaphoreParameters != NULL )
{
/* Create the semaphore used by the first two tasks. */
vSemaphoreCreateBinary( pxFirstSemaphoreParameters->xSemaphore );
if( pxFirstSemaphoreParameters->xSemaphore != NULL )
{
/* Create the variable which is to be shared by the first two tasks. */
pxFirstSemaphoreParameters->pulSharedVariable = ( unsigned long * ) pvPortMalloc( sizeof( unsigned long ) );
if( pxFirstSemaphoreParameters->xSemaphore != NULL )
{
/* Create the variable which is to be shared by the first two tasks. */
pxFirstSemaphoreParameters->pulSharedVariable = ( unsigned long * ) pvPortMalloc( sizeof( unsigned long ) );
/* Initialise the share variable to the value the tasks expect. */
*( pxFirstSemaphoreParameters->pulSharedVariable ) = semtstNON_BLOCKING_EXPECTED_VALUE;
/* Initialise the share variable to the value the tasks expect. */
*( pxFirstSemaphoreParameters->pulSharedVariable ) = semtstNON_BLOCKING_EXPECTED_VALUE;
/* The first two tasks do not block on semaphore calls. */
pxFirstSemaphoreParameters->xBlockTime = ( TickType_t ) 0;
/* The first two tasks do not block on semaphore calls. */
pxFirstSemaphoreParameters->xBlockTime = ( TickType_t ) 0;
/* Spawn the first two tasks. As they poll they operate at the idle priority. */
xTaskCreate( prvSemaphoreTest, "PolSEM1", semtstSTACK_SIZE, ( void * ) pxFirstSemaphoreParameters, tskIDLE_PRIORITY, ( TaskHandle_t * ) NULL );
xTaskCreate( prvSemaphoreTest, "PolSEM2", semtstSTACK_SIZE, ( void * ) pxFirstSemaphoreParameters, tskIDLE_PRIORITY, ( TaskHandle_t * ) NULL );
}
}
/* Spawn the first two tasks. As they poll they operate at the idle priority. */
xTaskCreate( prvSemaphoreTest, "PolSEM1", semtstSTACK_SIZE, ( void * ) pxFirstSemaphoreParameters, tskIDLE_PRIORITY, ( TaskHandle_t * ) NULL );
xTaskCreate( prvSemaphoreTest, "PolSEM2", semtstSTACK_SIZE, ( void * ) pxFirstSemaphoreParameters, tskIDLE_PRIORITY, ( TaskHandle_t * ) NULL );
}
}
/* Do exactly the same to create the second set of tasks, only this time
provide a block time for the semaphore calls. */
pxSecondSemaphoreParameters = ( xSemaphoreParameters * ) pvPortMalloc( sizeof( xSemaphoreParameters ) );
if( pxSecondSemaphoreParameters != NULL )
{
vSemaphoreCreateBinary( pxSecondSemaphoreParameters->xSemaphore );
/* Do exactly the same to create the second set of tasks, only this time
* provide a block time for the semaphore calls. */
pxSecondSemaphoreParameters = ( xSemaphoreParameters * ) pvPortMalloc( sizeof( xSemaphoreParameters ) );
if( pxSecondSemaphoreParameters->xSemaphore != NULL )
{
pxSecondSemaphoreParameters->pulSharedVariable = ( unsigned long * ) pvPortMalloc( sizeof( unsigned long ) );
*( pxSecondSemaphoreParameters->pulSharedVariable ) = semtstBLOCKING_EXPECTED_VALUE;
pxSecondSemaphoreParameters->xBlockTime = xBlockTime / portTICK_PERIOD_MS;
if( pxSecondSemaphoreParameters != NULL )
{
vSemaphoreCreateBinary( pxSecondSemaphoreParameters->xSemaphore );
xTaskCreate( prvSemaphoreTest, "BlkSEM1", semtstSTACK_SIZE, ( void * ) pxSecondSemaphoreParameters, uxPriority, ( TaskHandle_t * ) NULL );
xTaskCreate( prvSemaphoreTest, "BlkSEM2", semtstSTACK_SIZE, ( void * ) pxSecondSemaphoreParameters, uxPriority, ( TaskHandle_t * ) NULL );
}
}
if( pxSecondSemaphoreParameters->xSemaphore != NULL )
{
pxSecondSemaphoreParameters->pulSharedVariable = ( unsigned long * ) pvPortMalloc( sizeof( unsigned long ) );
*( pxSecondSemaphoreParameters->pulSharedVariable ) = semtstBLOCKING_EXPECTED_VALUE;
pxSecondSemaphoreParameters->xBlockTime = xBlockTime / portTICK_PERIOD_MS;
xTaskCreate( prvSemaphoreTest, "BlkSEM1", semtstSTACK_SIZE, ( void * ) pxSecondSemaphoreParameters, uxPriority, ( TaskHandle_t * ) NULL );
xTaskCreate( prvSemaphoreTest, "BlkSEM2", semtstSTACK_SIZE, ( void * ) pxSecondSemaphoreParameters, uxPriority, ( TaskHandle_t * ) NULL );
}
}
}
/*-----------------------------------------------------------*/
static void prvSemaphoreTest( void *pvParameters )
static void prvSemaphoreTest( void * pvParameters )
{
xSemaphoreParameters *pxParameters;
volatile unsigned long *pulSharedVariable, ulExpectedValue;
unsigned long ulCounter;
short sError = pdFALSE, sCheckVariableToUse;
xSemaphoreParameters * pxParameters;
volatile unsigned long * pulSharedVariable, ulExpectedValue;
unsigned long ulCounter;
short sError = pdFALSE, sCheckVariableToUse;
/* See which check variable to use. sNextCheckVariable is not semaphore
protected! */
portENTER_CRITICAL();
sCheckVariableToUse = sNextCheckVariable;
sNextCheckVariable++;
portEXIT_CRITICAL();
/* See which check variable to use. sNextCheckVariable is not semaphore
* protected! */
portENTER_CRITICAL();
sCheckVariableToUse = sNextCheckVariable;
sNextCheckVariable++;
portEXIT_CRITICAL();
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcSemaphoreTaskStart );
/* Queue a message for printing to say the task has started. */
vPrintDisplayMessage( &pcSemaphoreTaskStart );
/* A structure is passed in as the parameter. This contains the shared
variable being guarded. */
pxParameters = ( xSemaphoreParameters * ) pvParameters;
pulSharedVariable = pxParameters->pulSharedVariable;
/* A structure is passed in as the parameter. This contains the shared
* variable being guarded. */
pxParameters = ( xSemaphoreParameters * ) pvParameters;
pulSharedVariable = pxParameters->pulSharedVariable;
/* If we are blocking we use a much higher count to ensure loads of context
switches occur during the count. */
if( pxParameters->xBlockTime > ( TickType_t ) 0 )
{
ulExpectedValue = semtstBLOCKING_EXPECTED_VALUE;
}
else
{
ulExpectedValue = semtstNON_BLOCKING_EXPECTED_VALUE;
}
/* If we are blocking we use a much higher count to ensure loads of context
* switches occur during the count. */
if( pxParameters->xBlockTime > ( TickType_t ) 0 )
{
ulExpectedValue = semtstBLOCKING_EXPECTED_VALUE;
}
else
{
ulExpectedValue = semtstNON_BLOCKING_EXPECTED_VALUE;
}
for( ;; )
{
/* Try to obtain the semaphore. */
if( xSemaphoreTake( pxParameters->xSemaphore, pxParameters->xBlockTime ) == pdPASS )
{
/* We have the semaphore and so expect any other tasks using the
shared variable to have left it in the state we expect to find
it. */
if( *pulSharedVariable != ulExpectedValue )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
sError = pdTRUE;
}
/* Clear the variable, then count it back up to the expected value
before releasing the semaphore. Would expect a context switch or
two during this time. */
for( ulCounter = ( unsigned long ) 0; ulCounter <= ulExpectedValue; ulCounter++ )
{
*pulSharedVariable = ulCounter;
if( *pulSharedVariable != ulCounter )
{
if( sError == pdFALSE )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
}
sError = pdTRUE;
}
}
for( ; ; )
{
/* Try to obtain the semaphore. */
if( xSemaphoreTake( pxParameters->xSemaphore, pxParameters->xBlockTime ) == pdPASS )
{
/* We have the semaphore and so expect any other tasks using the
* shared variable to have left it in the state we expect to find
* it. */
if( *pulSharedVariable != ulExpectedValue )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
sError = pdTRUE;
}
/* Release the semaphore, and if no errors have occurred increment the check
variable. */
if( xSemaphoreGive( pxParameters->xSemaphore ) == pdFALSE )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
sError = pdTRUE;
}
/* Clear the variable, then count it back up to the expected value
* before releasing the semaphore. Would expect a context switch or
* two during this time. */
for( ulCounter = ( unsigned long ) 0; ulCounter <= ulExpectedValue; ulCounter++ )
{
*pulSharedVariable = ulCounter;
if( sError == pdFALSE )
{
if( sCheckVariableToUse < semtstNUM_TASKS )
{
( sCheckVariables[ sCheckVariableToUse ] )++;
}
}
if( *pulSharedVariable != ulCounter )
{
if( sError == pdFALSE )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
}
/* If we have a block time then we are running at a priority higher
than the idle priority. This task takes a long time to complete
a cycle (deliberately so to test the guarding) so will be starving
out lower priority tasks. Block for some time to allow give lower
priority tasks some processor time. */
vTaskDelay( pxParameters->xBlockTime * semtstDELAY_FACTOR );
}
else
{
if( pxParameters->xBlockTime == ( TickType_t ) 0 )
{
/* We have not got the semaphore yet, so no point using the
processor. We are not blocking when attempting to obtain the
semaphore. */
taskYIELD();
}
}
}
sError = pdTRUE;
}
}
/* Release the semaphore, and if no errors have occurred increment the check
* variable. */
if( xSemaphoreGive( pxParameters->xSemaphore ) == pdFALSE )
{
vPrintDisplayMessage( &pcPollingSemaphoreTaskError );
sError = pdTRUE;
}
if( sError == pdFALSE )
{
if( sCheckVariableToUse < semtstNUM_TASKS )
{
( sCheckVariables[ sCheckVariableToUse ] )++;
}
}
/* If we have a block time then we are running at a priority higher
* than the idle priority. This task takes a long time to complete
* a cycle (deliberately so to test the guarding) so will be starving
* out lower priority tasks. Block for some time to allow give lower
* priority tasks some processor time. */
vTaskDelay( pxParameters->xBlockTime * semtstDELAY_FACTOR );
}
else
{
if( pxParameters->xBlockTime == ( TickType_t ) 0 )
{
/* We have not got the semaphore yet, so no point using the
* processor. We are not blocking when attempting to obtain the
* semaphore. */
taskYIELD();
}
}
}
}
/*-----------------------------------------------------------*/
/* This is called to check that all the created tasks are still running. */
BaseType_t xAreSemaphoreTasksStillRunning( void )
{
static short sLastCheckVariables[ semtstNUM_TASKS ] = { 0 };
portBASE_TYPE xTask, xReturn = pdTRUE;
static short sLastCheckVariables[ semtstNUM_TASKS ] = { 0 };
portBASE_TYPE xTask, xReturn = pdTRUE;
for( xTask = 0; xTask < semtstNUM_TASKS; xTask++ )
{
if( sLastCheckVariables[ xTask ] == sCheckVariables[ xTask ] )
{
xReturn = pdFALSE;
}
for( xTask = 0; xTask < semtstNUM_TASKS; xTask++ )
{
if( sLastCheckVariables[ xTask ] == sCheckVariables[ xTask ] )
{
xReturn = pdFALSE;
}
sLastCheckVariables[ xTask ] = sCheckVariables[ xTask ];
}
sLastCheckVariables[ xTask ] = sCheckVariables[ xTask ];
}
return xReturn;
return xReturn;
}