2 FreeRTOS V7.0.1 - Copyright (C) 2011 Real Time Engineers Ltd.
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5 ***************************************************************************
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7 * FreeRTOS tutorial books are available in pdf and paperback. *
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8 * Complete, revised, and edited pdf reference manuals are also *
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11 * Purchasing FreeRTOS documentation will not only help you, by *
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12 * ensuring you get running as quickly as possible and with an *
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13 * in-depth knowledge of how to use FreeRTOS, it will also help *
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14 * the FreeRTOS project to continue with its mission of providing *
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15 * professional grade, cross platform, de facto standard solutions *
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16 * for microcontrollers - completely free of charge! *
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18 * >>> See http://www.FreeRTOS.org/Documentation for details. <<< *
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20 * Thank you for using FreeRTOS, and thank you for your support! *
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22 ***************************************************************************
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25 This file is part of the FreeRTOS distribution.
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27 FreeRTOS is free software; you can redistribute it and/or modify it under
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28 the terms of the GNU General Public License (version 2) as published by the
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29 Free Software Foundation AND MODIFIED BY the FreeRTOS exception.
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30 >>>NOTE<<< The modification to the GPL is included to allow you to
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31 distribute a combined work that includes FreeRTOS without being obliged to
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32 provide the source code for proprietary components outside of the FreeRTOS
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33 kernel. FreeRTOS is distributed in the hope that it will be useful, but
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34 WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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35 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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36 more details. You should have received a copy of the GNU General Public
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37 License and the FreeRTOS license exception along with FreeRTOS; if not it
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38 can be viewed here: http://www.freertos.org/a00114.html and also obtained
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39 by writing to Richard Barry, contact details for whom are available on the
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44 http://www.FreeRTOS.org - Documentation, latest information, license and
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47 http://www.SafeRTOS.com - A version that is certified for use in safety
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50 http://www.OpenRTOS.com - Commercial support, development, porting,
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51 licensing and training services.
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55 * The documentation page for this demo available on http://www.FreeRTOS.org
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56 * documents the hardware configuration required to run this demo. It also
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57 * provides more information on the expected demo application behaviour.
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59 * main() creates all the demo application tasks, then starts the scheduler.
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60 * A lot of the created tasks are from the pool of "standard demo" tasks. The
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61 * web documentation provides more details of the standard demo tasks, which
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62 * provide no particular functionality but do provide good examples of how to
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63 * use the FreeRTOS API.
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65 * In addition to the standard demo tasks, the following tasks, interrupts tests
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66 * and timers are defined and/or created within this file:
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68 * "LCD" task - The LCD task is a 'gatekeeper' task. It is the only task that
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69 * is permitted to access the LCD and therefore ensures access to the LCD is
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70 * always serialised and there are no mutual exclusion issues. When a task or
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71 * an interrupt wants to write to the LCD, it does not access the LCD directly
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72 * but instead sends the message to the LCD task. The LCD task then performs
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73 * the actual LCD output. This mechanism also allows interrupts to, in effect,
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74 * write to the LCD by sending messages to the LCD task.
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76 * The LCD task is also a demonstration of a 'controller' task design pattern.
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77 * Some tasks do not actually send a string to the LCD task directly, but
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78 * instead send a command that is interpreted by the LCD task. In a normal
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79 * application these commands can be control values or set points, in this
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80 * simple example the commands just result in messages being displayed on the
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83 * "Button Poll" task - This task polls the state of the 'up' key on the
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84 * joystick input device. It uses the vTaskDelay() API function to control
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85 * the poll rate to ensure debouncing is not necessary and that the task does
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86 * not use all the available CPU processing time.
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88 * Button Interrupt - The select button on the joystick input device is
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89 * configured to generate an external interrupt. The handler for this interrupt
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90 * sends a message to LCD task, which then prints out a string to say the
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91 * joystick select button was pressed.
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93 * Idle Hook - The idle hook is a function that is called on each iteration of
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94 * the idle task. In this case it is used to place the processor into a low
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95 * power mode. Note however that this application is implemented using standard
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96 * components, and is therefore not optimised for low power operation. Lower
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97 * power consumption would be achieved by converting polling tasks into event
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98 * driven tasks, and slowing the tick interrupt frequency, etc.
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100 * "Check" callback function - Called each time the 'check' timer expires. The
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101 * check timer executes every five seconds. Its main function is to check that
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102 * all the standard demo tasks are still operational. Each time it executes it
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103 * sends a status code to the LCD task. The LCD task interprets the code and
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104 * displays an appropriate message - which will be PASS if no tasks have
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105 * reported any errors, or a message stating which task has reported an error.
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107 * "Reg test" tasks - These fill the registers with known values, then check
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108 * that each register still contains its expected value. Each task uses
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109 * different values. The tasks run with very low priority so get preempted
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110 * very frequently. A check variable is incremented on each iteration of the
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111 * test loop. A register containing an unexpected value is indicative of an
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112 * error in the context switching mechanism and will result in a branch to a
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113 * null loop - which in turn will prevent the check variable from incrementing
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114 * any further and allow the check timer callback (described a above) to
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115 * determine that an error has occurred. The nature of the reg test tasks
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116 * necessitates that they are written in assembly code.
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118 * Tick hook function - called inside the RTOS tick function, this simple
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119 * example does nothing but toggle an LED.
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121 * *NOTE 1* vApplicationSetupTimerInterrupt() is called by the kernel to let
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122 * the application set up a timer to generate the tick interrupt. In this
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123 * example a timer A0 is used for this purpose.
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127 /* Standard includes. */
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130 /* FreeRTOS includes. */
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131 #include "FreeRTOS.h"
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133 #include "timers.h"
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136 /* Hardware includes. */
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137 #include "msp430.h"
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138 #include "hal_MSP-EXP430F5438.h"
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140 /* Standard demo includes. */
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141 #include "ParTest.h"
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142 #include "dynamic.h"
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143 #include "comtest2.h"
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144 #include "GenQTest.h"
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145 #include "TimerDemo.h"
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146 #include "countsem.h"
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148 /* Codes sent within messages to the LCD task so the LCD task can interpret
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149 exactly what the message it just received was. These are sent in the
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150 cMessageID member of the message structure (defined below). */
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151 #define mainMESSAGE_BUTTON_UP ( 1 )
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152 #define mainMESSAGE_BUTTON_SEL ( 2 )
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153 #define mainMESSAGE_STATUS ( 3 )
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155 /* When the cMessageID member of the message sent to the LCD task is
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156 mainMESSAGE_STATUS then these definitions are sent in the ulMessageValue member
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157 of the same message and indicate what the status actually is. */
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158 #define mainERROR_DYNAMIC_TASKS ( pdPASS + 1 )
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159 #define mainERROR_COM_TEST ( pdPASS + 2 )
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160 #define mainERROR_GEN_QUEUE_TEST ( pdPASS + 3 )
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161 #define mainERROR_REG_TEST ( pdPASS + 4 )
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162 #define mainERROR_TIMER_TEST ( pdPASS + 5 )
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163 #define mainERROR_COUNT_SEM_TEST ( pdPASS + 6 )
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165 /* The length of the queue (the number of items the queue can hold) that is used
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166 to send messages from tasks and interrupts the the LCD task. */
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167 #define mainQUEUE_LENGTH ( 5 )
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169 /* Priorities used by the test and demo tasks. */
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170 #define mainLCD_TASK_PRIORITY ( tskIDLE_PRIORITY + 1 )
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171 #define mainCOM_TEST_PRIORITY ( tskIDLE_PRIORITY + 2 )
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172 #define mainGENERIC_QUEUE_TEST_PRIORITY ( tskIDLE_PRIORITY )
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174 /* The LED used by the comtest tasks. See the comtest.c file for more
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176 #define mainCOM_TEST_LED ( 1 )
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178 /* The baud rate used by the comtest tasks. */
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179 #define mainCOM_TEST_BAUD_RATE ( 38400 )
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181 /* The maximum number of lines of text that can be displayed on the LCD. */
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182 #define mainMAX_LCD_LINES ( 8 )
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184 /* Just used to ensure parameters are passed into tasks correctly. */
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185 #define mainTASK_PARAMETER_CHECK_VALUE ( ( void * ) 0xDEAD )
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187 /* The base period used by the timer test tasks. */
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188 #define mainTIMER_TEST_PERIOD ( 50 )
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190 /* The frequency at which the check timer (described in the comments at the top
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191 of this file) will call its callback function. */
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192 #define mainCHECK_TIMER_PERIOD ( 5000UL / ( unsigned long ) portTICK_RATE_MS )
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195 #define mainDONT_BLOCK ( 0 )
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196 /*-----------------------------------------------------------*/
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199 * The reg test tasks as described at the top of this file.
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201 extern void vRegTest1Task( void *pvParameters );
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202 extern void vRegTest2Task( void *pvParameters );
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205 * Configures clocks, LCD, port pints, etc. necessary to execute this demo.
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207 static void prvSetupHardware( void );
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210 * Definition of the LCD/controller task described in the comments at the top
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213 static void prvLCDTask( void *pvParameters );
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216 * Definition of the button poll task described in the comments at the top of
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219 static void prvButtonPollTask( void *pvParameters );
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222 * Converts a status message value into an appropriate string for display on
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223 * the LCD. The string is written to pcBuffer.
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225 static void prvGenerateStatusMessage( char *pcBuffer, unsigned long ulStatusValue );
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228 * Defines the 'check' functionality as described at the top of this file. This
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229 * function is the callback function for the 'check' timer. */
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230 static void vCheckTimerCallback( xTimerHandle xTimer );
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232 /*-----------------------------------------------------------*/
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234 /* Variables that are incremented on each iteration of the reg test tasks -
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235 provided the tasks have not reported any errors. The check task inspects these
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236 variables to ensure they are still incrementing as expected. If a variable
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237 stops incrementing then it is likely that its associate task has stalled. */
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238 volatile unsigned short usRegTest1Counter = 0, usRegTest2Counter = 0;
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240 /* The handle of the queue used to send messages from tasks and interrupts to
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242 static xQueueHandle xLCDQueue = NULL;
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244 /* The 'check' timer, as described at the top of this file. */
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245 static xTimerHandle xCheckTimer = NULL;
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247 /* The definition of each message sent from tasks and interrupts to the LCD
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251 char cMessageID; /* << States what the message is. */
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252 unsigned long ulMessageValue; /* << States the message value (can be an integer, string pointer, etc. depending on the value of cMessageID). */
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255 /*-----------------------------------------------------------*/
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259 /* Configure the peripherals used by this demo application. This includes
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260 configuring the joystick input select button to generate interrupts. */
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261 prvSetupHardware();
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263 /* Create the queue used by tasks and interrupts to send strings to the LCD
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265 xLCDQueue = xQueueCreate( mainQUEUE_LENGTH, sizeof( xQueueMessage ) );
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267 /* If the queue could not be created then don't create any tasks that might
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268 attempt to use the queue. */
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269 if( xLCDQueue != NULL )
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271 /* Create the standard demo tasks. */
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272 vAltStartComTestTasks( mainCOM_TEST_PRIORITY, mainCOM_TEST_BAUD_RATE, mainCOM_TEST_LED );
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273 vStartDynamicPriorityTasks();
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274 vStartGenericQueueTasks( mainGENERIC_QUEUE_TEST_PRIORITY );
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275 vStartCountingSemaphoreTasks();
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277 /* Note that creating the timer test/demo tasks will fill the timer
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278 command queue. This is intentional, and forms part of the test the tasks
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279 perform. It does mean however that, after this function is called, no
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280 more timer commands can be sent until after the scheduler has been
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281 started (at which point the timer daemon will drained the timer command
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282 queue, freeing up space for more commands to be received). */
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283 vStartTimerDemoTask( mainTIMER_TEST_PERIOD );
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285 /* Create the LCD, button poll and register test tasks, as described at
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286 the top of this file. */
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287 xTaskCreate( prvLCDTask, ( signed char * ) "LCD", configMINIMAL_STACK_SIZE * 2, mainTASK_PARAMETER_CHECK_VALUE, mainLCD_TASK_PRIORITY, NULL );
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288 xTaskCreate( prvButtonPollTask, ( signed char * ) "BPoll", configMINIMAL_STACK_SIZE, NULL, tskIDLE_PRIORITY, NULL );
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289 xTaskCreate( vRegTest1Task, ( signed char * ) "Reg1", configMINIMAL_STACK_SIZE, NULL, 0, NULL );
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290 xTaskCreate( vRegTest2Task, ( signed char * ) "Reg2", configMINIMAL_STACK_SIZE, NULL, 0, NULL );
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292 /* Create the 'check' timer - the timer that periodically calls the
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293 check function as described at the top of this file. Note that, for
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294 the reasons stated in the comments above the call to
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295 vStartTimerDemoTask(), that the check timer is not actually started
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296 until after the scheduler has been started. */
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297 xCheckTimer = xTimerCreate( ( const signed char * ) "Check timer", mainCHECK_TIMER_PERIOD, pdTRUE, ( void * ) 0, vCheckTimerCallback );
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299 /* Start the scheduler. */
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300 vTaskStartScheduler();
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303 /* If all is well then this line will never be reached. If it is reached
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304 then it is likely that there was insufficient (FreeRTOS) heap memory space
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305 to create the idle task. This may have been trapped by the malloc() failed
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306 hook function, if one is configured. */
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309 /*-----------------------------------------------------------*/
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311 static void prvLCDTask( void *pvParameters )
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313 xQueueMessage xReceivedMessage;
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315 /* Buffer into which strings are formatted and placed ready for display on the
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316 LCD. Note this is a static variable to prevent it being allocated on the task
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317 stack, which is too small to hold such a variable. The stack size is configured
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318 when the task is created. */
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319 static char cBuffer[ 50 ];
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320 unsigned char ucLine = 1;
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322 /* Now the scheduler has been started (it must have been for this task to
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323 be running), start the check timer too. The call to xTimerStart() will
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324 block until the command has been accepted. */
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325 if( xCheckTimer != NULL )
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327 xTimerStart( xCheckTimer, portMAX_DELAY );
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330 /* This is the only function that is permitted to access the LCD.
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332 First print out the number of bytes that remain in the FreeRTOS heap. This
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333 is done after a short delay to ensure all the demo tasks have created all
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334 the objects they are going to use. */
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335 vTaskDelay( mainTIMER_TEST_PERIOD * 10 );
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336 sprintf( cBuffer, "%d heap free", ( int ) xPortGetFreeHeapSize() );
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337 halLcdPrintLine( cBuffer, ucLine, OVERWRITE_TEXT );
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340 /* Just as a test of the port, and for no functional reason, check the task
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341 parameter contains its expected value. */
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342 if( pvParameters != mainTASK_PARAMETER_CHECK_VALUE )
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344 halLcdPrintLine( "Invalid parameter", ucLine, OVERWRITE_TEXT );
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350 /* Wait for a message to be received. Using portMAX_DELAY as the block
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351 time will result in an indefinite wait provided INCLUDE_vTaskSuspend is
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352 set to 1 in FreeRTOSConfig.h, therefore there is no need to check the
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353 function return value and the function will only return when a value
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354 has been received. */
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355 xQueueReceive( xLCDQueue, &xReceivedMessage, portMAX_DELAY );
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357 /* Clear the LCD if no room remains for any more text output. */
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358 if( ucLine > mainMAX_LCD_LINES )
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360 halLcdClearScreen();
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364 /* What is this message? What does it contain? */
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365 switch( xReceivedMessage.cMessageID )
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367 case mainMESSAGE_BUTTON_UP : /* The button poll task has just
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368 informed this task that the up
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369 button on the joystick input has
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370 been pressed or released. */
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371 sprintf( cBuffer, "Button up = %d", ( int ) xReceivedMessage.ulMessageValue );
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374 case mainMESSAGE_BUTTON_SEL : /* The select button interrupt
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375 just informed this task that the
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376 select button has been pressed.
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377 In this case the pointer to the
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378 string to print is sent directly
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379 in the ulMessageValue member of
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380 the message. This just
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381 demonstrates a different
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382 communication technique. */
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383 sprintf( cBuffer, "%s", ( char * ) xReceivedMessage.ulMessageValue );
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386 case mainMESSAGE_STATUS : /* The tick interrupt hook
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387 function has just informed this
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388 task of the system status.
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389 Generate a string in accordance
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390 with the status value. */
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391 prvGenerateStatusMessage( cBuffer, xReceivedMessage.ulMessageValue );
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394 default : sprintf( cBuffer, "Unknown message" );
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398 /* Output the message that was placed into the cBuffer array within the
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399 switch statement above, then move onto the next line ready for the next
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400 message to arrive on the queue. */
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401 halLcdPrintLine( cBuffer, ucLine, OVERWRITE_TEXT );
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405 /*-----------------------------------------------------------*/
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407 static void prvGenerateStatusMessage( char *pcBuffer, unsigned long ulStatusValue )
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409 /* Just a utility function to convert a status value into a meaningful
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410 string for output onto the LCD. */
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411 switch( ulStatusValue )
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413 case pdPASS : sprintf( pcBuffer, "Status = PASS" );
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415 case mainERROR_DYNAMIC_TASKS : sprintf( pcBuffer, "Err: Dynamic tsks" );
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417 case mainERROR_COM_TEST : sprintf( pcBuffer, "Err: COM test" );
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419 case mainERROR_GEN_QUEUE_TEST : sprintf( pcBuffer, "Error: Gen Q test" );
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421 case mainERROR_REG_TEST : sprintf( pcBuffer, "Error: Reg test" );
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423 case mainERROR_TIMER_TEST : sprintf( pcBuffer, "Error: Tmr test" );
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425 case mainERROR_COUNT_SEM_TEST : sprintf( pcBuffer, "Error: Count sem" );
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427 default : sprintf( pcBuffer, "Unknown status" );
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431 /*-----------------------------------------------------------*/
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433 static void prvButtonPollTask( void *pvParameters )
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435 unsigned char ucLastState = pdFALSE, ucState;
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436 xQueueMessage xMessage;
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438 /* This tasks performs the button polling functionality as described at the
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439 top of this file. */
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442 /* Check the button state. */
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443 ucState = ( halButtonsPressed() & BUTTON_UP );
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447 /* The button was pressed. */
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451 if( ucState != ucLastState )
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453 /* The state has changed, send a message to the LCD task. */
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454 xMessage.cMessageID = mainMESSAGE_BUTTON_UP;
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455 xMessage.ulMessageValue = ( unsigned long ) ucState;
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456 ucLastState = ucState;
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457 xQueueSend( xLCDQueue, &xMessage, portMAX_DELAY );
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460 /* Block for 10 milliseconds so this task does not utilise all the CPU
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461 time and debouncing of the button is not necessary. */
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462 vTaskDelay( 10 / portTICK_RATE_MS );
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465 /*-----------------------------------------------------------*/
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467 static void vCheckTimerCallback( xTimerHandle xTimer )
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469 static unsigned short usLastRegTest1Counter = 0, usLastRegTest2Counter = 0;
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471 /* Define the status message that is sent to the LCD task. By default the
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473 static xQueueMessage xStatusMessage = { mainMESSAGE_STATUS, pdPASS };
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475 /* This is the callback function used by the 'check' timer, as described
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476 at the top of this file. */
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478 /* The parameter is not used. */
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481 /* See if the standard demo tasks are executing as expected, changing
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482 the message that is sent to the LCD task from PASS to an error code if
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483 any tasks set reports an error. */
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484 if( xAreComTestTasksStillRunning() != pdPASS )
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486 xStatusMessage.ulMessageValue = mainERROR_COM_TEST;
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489 if( xAreDynamicPriorityTasksStillRunning() != pdPASS )
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491 xStatusMessage.ulMessageValue = mainERROR_DYNAMIC_TASKS;
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494 if( xAreGenericQueueTasksStillRunning() != pdPASS )
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496 xStatusMessage.ulMessageValue = mainERROR_GEN_QUEUE_TEST;
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499 if( xAreCountingSemaphoreTasksStillRunning() != pdPASS )
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501 xStatusMessage.ulMessageValue = mainERROR_COUNT_SEM_TEST;
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504 if( xAreTimerDemoTasksStillRunning( ( portTickType ) mainCHECK_TIMER_PERIOD ) != pdPASS )
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506 xStatusMessage.ulMessageValue = mainERROR_TIMER_TEST;
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509 /* Check the reg test tasks are still cycling. They will stop
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510 incrementing their loop counters if they encounter an error. */
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511 if( usRegTest1Counter == usLastRegTest1Counter )
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513 xStatusMessage.ulMessageValue = mainERROR_REG_TEST;
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516 if( usRegTest2Counter == usLastRegTest2Counter )
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518 xStatusMessage.ulMessageValue = mainERROR_REG_TEST;
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521 usLastRegTest1Counter = usRegTest1Counter;
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522 usLastRegTest2Counter = usRegTest2Counter;
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524 /* This is called from a timer callback so must not block! */
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525 xQueueSendToBack( xLCDQueue, &xStatusMessage, mainDONT_BLOCK );
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527 /*-----------------------------------------------------------*/
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529 static void prvSetupHardware( void )
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531 /* Convert a Hz value to a KHz value, as required by the Init_FLL_Settle()
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533 unsigned long ulCPU_Clock_KHz = ( configCPU_CLOCK_HZ / 1000UL );
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535 taskDISABLE_INTERRUPTS();
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537 /* Disable the watchdog. */
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538 WDTCTL = WDTPW + WDTHOLD;
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542 LFXT_Start( XT1DRIVE_0 );
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543 Init_FLL_Settle( ( unsigned short ) ulCPU_Clock_KHz, 488 );
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545 halButtonsInit( BUTTON_ALL );
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546 halButtonsInterruptEnable( BUTTON_SELECT );
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548 /* Initialise the LCD, but note that the backlight is not used as the
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549 library function uses timer A0 to modulate the backlight, and this file
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550 defines vApplicationSetupTimerInterrupt() to also use timer A0 to generate
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551 the tick interrupt. If the backlight is required, then change either the
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552 halLCD library or vApplicationSetupTimerInterrupt() to use a different
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553 timer. Timer A1 is used for the run time stats time base6. */
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555 halLcdSetContrast( 100 );
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556 halLcdClearScreen();
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558 halLcdPrintLine( " www.FreeRTOS.org", 0, OVERWRITE_TEXT );
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560 /*-----------------------------------------------------------*/
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563 void vApplicationTickHook( void )
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565 static unsigned long ulCounter = 0;
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567 /* Is it time to toggle the LED again? */
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570 /* Just periodically toggle an LED to show that the tick interrupt is
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571 running. Note that this access LED_PORT_OUT in a non-atomic way, so tasks
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572 that access the same port must do so from a critical section. */
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573 if( ( ulCounter & 0xff ) == 0 )
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575 if( ( LED_PORT_OUT & LED_1 ) == 0 )
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577 LED_PORT_OUT |= LED_1;
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581 LED_PORT_OUT &= ~LED_1;
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585 /*-----------------------------------------------------------*/
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587 #pragma vector=PORT2_VECTOR
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588 interrupt void prvSelectButtonInterrupt( void )
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590 /* Define the message sent to the LCD task from this interrupt. */
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591 static const xQueueMessage xMessage = { mainMESSAGE_BUTTON_SEL, ( unsigned long ) "Select Interrupt" };
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592 portBASE_TYPE xHigherPriorityTaskWoken = pdFALSE;
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594 /* This is the interrupt handler for the joystick select button input.
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595 The button has been pushed, write a message to the LCD via the LCD task. */
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596 xQueueSendFromISR( xLCDQueue, &xMessage, &xHigherPriorityTaskWoken );
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600 /* If writing to xLCDQueue caused a task to unblock, and the unblocked task
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601 has a priority equal to or above the task that this interrupt interrupted,
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602 then lHigherPriorityTaskWoken will have been set to pdTRUE internally within
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603 xQueuesendFromISR(), and portEND_SWITCHING_ISR() will ensure that this
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604 interrupt returns directly to the higher priority unblocked task. */
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605 portYIELD_FROM_ISR( xHigherPriorityTaskWoken );
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607 /*-----------------------------------------------------------*/
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609 /* The MSP430X port uses this callback function to configure its tick interrupt.
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610 This allows the application to choose the tick interrupt source.
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611 configTICK_VECTOR must also be set in FreeRTOSConfig.h to the correct
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612 interrupt vector for the chosen tick interrupt source. This implementation of
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613 vApplicationSetupTimerInterrupt() generates the tick from timer A0, so in this
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614 case configTICK_VECTOR is set to TIMER0_A0_VECTOR. */
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615 void vApplicationSetupTimerInterrupt( void )
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617 const unsigned short usACLK_Frequency_Hz = 32768;
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619 /* Ensure the timer is stopped. */
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622 /* Run the timer from the ACLK. */
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625 /* Clear everything to start with. */
\r
628 /* Set the compare match value according to the tick rate we want. */
\r
629 TA0CCR0 = usACLK_Frequency_Hz / configTICK_RATE_HZ;
\r
631 /* Enable the interrupts. */
\r
634 /* Start up clean. */
\r
640 /*-----------------------------------------------------------*/
\r
642 void vApplicationIdleHook( void )
\r
644 /* Called on each iteration of the idle task. In this case the idle task
\r
645 just enters a low(ish) power mode. */
\r
646 __bis_SR_register( LPM1_bits + GIE );
\r
648 /*-----------------------------------------------------------*/
\r
650 void vApplicationMallocFailedHook( void )
\r
652 /* Called if a call to pvPortMalloc() fails because there is insufficient
\r
653 free memory available in the FreeRTOS heap. pvPortMalloc() is called
\r
654 internally by FreeRTOS API functions that create tasks, queues or
\r
656 taskDISABLE_INTERRUPTS();
\r
659 /*-----------------------------------------------------------*/
\r
661 void vApplicationStackOverflowHook( xTaskHandle *pxTask, signed char *pcTaskName )
\r
664 ( void ) pcTaskName;
\r
666 /* Run time stack overflow checking is performed if
\r
667 configconfigCHECK_FOR_STACK_OVERFLOW is defined to 1 or 2. This hook
\r
668 function is called if a stack overflow is detected. */
\r
669 taskDISABLE_INTERRUPTS();
\r
672 /*-----------------------------------------------------------*/
\r