Difference between revisions of "Embedded System Tutorial File I/O"

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(Assignment)
(Assignment)
Line 6: Line 6:
 
#  Create a '''<code>producer task</code>''' that takes 1 light sensor value every 1ms.
 
#  Create a '''<code>producer task</code>''' that takes 1 light sensor value every 1ms.
 
#*  Collect the average of the 100 readings.
 
#*  Collect the average of the 100 readings.
#*  Write average value of 100ms (100 samples) to the '''<code>sensor queue</code>'''.
+
#*  Write average value every 100ms (100 samples) to the '''<code>sensor queue</code>'''.
 
#*  Use medium priority for this task
 
#*  Use medium priority for this task
 
#  Create a '''<code>consumer task</code>''' that pulls the data off the '''<code>sensor queue</code>'''  
 
#  Create a '''<code>consumer task</code>''' that pulls the data off the '''<code>sensor queue</code>'''  

Revision as of 00:59, 10 May 2014

In this project, we will attempt to "combine" all the FreeRTOS knowledge into a single assignment.

Assignment

Please follow the steps precisely in order to complete the objectives of the assignment. If you use the C++ FreeRTOS framework, it should make the assignment significantly easy.

  1. Create a producer task that takes 1 light sensor value every 1ms.
    • Collect the average of the 100 readings.
    • Write average value every 100ms (100 samples) to the sensor queue.
    • Use medium priority for this task
  2. Create a consumer task that pulls the data off the sensor queue
    • Use infinite timeout value during queue receive API
    • Open a file (sensor.txt), and append the data to an output file on the SD card.
    • Save the data in this format: printf("%i, %i\n", time, light)"
    • Just leave the file in "open" mode, such that it will flush the data after enough data is written rather than flushing it upon each write, which will consume a lot of CPU.
    • Use medium priority for this task
  3. Create a watchdog task that monitors the operation of the two tasks.
    • Use high priority for this task.
    • Every sixty seconds, save the CPU usage info to a file named "cpu.txt". See terminal command "infoHandler" for reference. Open the file, write the file, and close it immediately so the data is immediately flushed.
    • Towards the end of the other tasks, set a bit using the xEventGroupSetBits()
    • Task 1 should set bit1, Task 2 should set bit2 etc.
    • Use a timeout of 1 second, and wait for all the bits to set. If there are two tasks, wait for bit1, and bit2 etc.
    • If you fail to detect the bits are set, that means that the other tasks did not reach the end of the loop.
    • In the event of failed to detect the bits, append a file (stuck.txt) with the information about which task may be "stuck"
    • Open the file, append the data, and close the (stuck.txt) file to flush out the data immediately.
  4. Create a terminal command to "suspend" and "resume" a task by name.
    • "task suspend task1" should suspend a task named "task1"
    • "task resume task2" should suspend a task named "task2"
  5. Run the system, and under normal operation, you will see a file being saved with sensor data values.
    • Plot the file data in Excel to demonstrate.
  6. Suspend the producer task. The watchdog task should display a message and save relevant info to the SD card.
  7. Let the system run for a while, and note down the CPU usage in your text file.
  8. Change the ADC sensor implementation
    • Modify the source code of how the light sensor class obtains the ADC value by not using ADC polling mode.
    • Instead of "trigger ADC", "wait for completion", and "read value", modify it to this:
      Upon ADC initialization, enable ADC interrupt, which should "give" a semaphore.
      After triggering the ADC, wait for ADC semaphore to be given, and then read the value.
  9. After changing the ADC behavior, let the system run for a while, and note down the CPU usage again.

What you created is a "software watchdog". This means that in an event when a loop is stuck, or a task is frozen, you can save relevant information such that you can debug at a later time.

After completing the assignment, you will get a sensor of how the CPU is utilized, and how to use a new FreeRTOS event group API. All together, you should acheive a better sensor of designing your tasks and using the File I/O for debugging purposes.