samples/userspace/prod_consumer/README.rst - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 .. _userspace_prod_consumer:

 Producer/consumer
 =================

 This is a sample application that exercises some user mode concepts.

 Overview
 ********

 Consider a "sample driver" which gets incoming data from some unknown source
 and generates interrupts with pointers to this data. The application needs
 to perform some processing on this data and then write the processed data
 back to the driver.

 The goal here is to demonstrate:

  - Multiple logical applications, each with their own memory domain
  - Creation of a sys_heap and assignment to a memory partition
  - Use of APIs like ``k_queue_alloc_append()`` which require thread resource
    pools to be configured
  - Management of permissions for kernel objects and drivers
  - Show how application-specific system calls are defined
  - Show IPC between ISR and application (using ``k_msgq``) and
    application-to-application IPC (using ``k_queue``)
  - Show how to create application-specific system calls

 In this example, we have an Application A whose job is to talk to the
 driver, buffer incoming data, and write it back once processed by
 Application B.

 Application B simply processes the data. Let's pretend this data is
 untrusted and possibly malicious, so Application B is sandboxed from
 everything else, with just two queues for sending/receiving data items.

 The control loop is as follows:

  - Sample driver issues interrupts, invoking its associated callback
    function with a fixed-sized data payload.
  - App A callback function, in supervisor mode, places the data payload
    into a message queue.
  - App A monitor thread in user mode waits for data in the message queue.
    When it wakes up, copy the data payload into a buffer allocated out
    of the shared memory pool, and enqueue this data into a ``k_queue`` being
    monitored by application B.
  - Application B processing thread waits on new items in the queue. It
    then processes the data in-place, and after it's finished it places
    the processed data into another queue to be written back to the driver.
  - Application A writeback thread monitors the outgoing data queue for
    new items containing processed data. As it gets them it will write
    such data back to the driver and free the buffer.

 We also demonstrate application-defined system calls, in the form of
 the ``magic_cookie()`` function.

 Sample Output
 *************

 .. code-block:: console

     I:APP A partition: 0x00110000 4096
     I:Shared partition: 0x0010e000 4096
     I:sample_driver_foo_isr: param=0x00147078 count=0
     I:monitor thread got data payload #0
     I:sample_driver_foo_isr: param=0x00147078 count=1
     I:monitor thread got data payload #1
     I:sample_driver_foo_isr: param=0x00147078 count=2
     I:monitor thread got data payload #2
     I:sample_driver_foo_isr: param=0x00147078 count=3
     I:monitor thread got data payload #3
     I:sample_driver_foo_isr: param=0x00147078 count=4
     I:monitor thread got data payload #4
     I:processing payload #1 complete
     I:writing processed data blob back to the sample device
     I:sample_driver_foo_isr: param=0x00147078 count=5
     I:monitor thread got data payload #5
     I:processing payload #2 complete
     I:writing processed data blob back to the sample device
     I:sample_driver_foo_isr: param=0x00147078 count=6
     I:monitor thread got data payload #6
     I:processing payload #3 complete
     I:writing processed data blob back to the sample device
     I:sample_driver_foo_isr: param=0x00147078 count=7
     I:monitor thread got data payload #7
     I:processing payload #4 complete
     I:writing processed data blob back to the sample device
     I:sample_driver_foo_isr: param=0x00147078 count=8
     I:monitor thread got data payload #8
     I:processing payload #5 complete
     I:writing processed data blob back to the sample device
     I:sample_driver_foo_isr: param=0x00147078 count=9
     I:monitor thread got data payload #9
     I:processing payload #6 complete
     I:writing processed data blob back to the sample device
     I:processing payload #7 complete
     I:writing processed data blob back to the sample device
     I:processing payload #8 complete
     I:writing processed data blob back to the sample device
     I:processing payload #9 complete
     I:writing processed data blob back to the sample device
     I:processing payload #10 complete
     I:writing processed data blob back to the sample device
     I:SUCCESS
	.. _userspace_prod_consumer:

	Producer/consumer
	=================

	This is a sample application that exercises some user mode concepts.

	Overview
	********

	Consider a "sample driver" which gets incoming data from some unknown source
	and generates interrupts with pointers to this data. The application needs
	to perform some processing on this data and then write the processed data
	back to the driver.

	The goal here is to demonstrate:

	- Multiple logical applications, each with their own memory domain
	- Creation of a sys_heap and assignment to a memory partition
	- Use of APIs like ``k_queue_alloc_append()`` which require thread resource
	pools to be configured
	- Management of permissions for kernel objects and drivers
	- Show how application-specific system calls are defined
	- Show IPC between ISR and application (using ``k_msgq``) and
	application-to-application IPC (using ``k_queue``)
	- Show how to create application-specific system calls

	In this example, we have an Application A whose job is to talk to the
	driver, buffer incoming data, and write it back once processed by
	Application B.

	Application B simply processes the data. Let's pretend this data is
	untrusted and possibly malicious, so Application B is sandboxed from
	everything else, with just two queues for sending/receiving data items.

	The control loop is as follows:

	- Sample driver issues interrupts, invoking its associated callback
	function with a fixed-sized data payload.
	- App A callback function, in supervisor mode, places the data payload
	into a message queue.
	- App A monitor thread in user mode waits for data in the message queue.
	When it wakes up, copy the data payload into a buffer allocated out
	of the shared memory pool, and enqueue this data into a ``k_queue`` being
	monitored by application B.
	- Application B processing thread waits on new items in the queue. It
	then processes the data in-place, and after it's finished it places
	the processed data into another queue to be written back to the driver.
	- Application A writeback thread monitors the outgoing data queue for
	new items containing processed data. As it gets them it will write
	such data back to the driver and free the buffer.

	We also demonstrate application-defined system calls, in the form of
	the ``magic_cookie()`` function.

	Sample Output
	*************

	.. code-block:: console

	I:APP A partition: 0x00110000 4096
	I:Shared partition: 0x0010e000 4096
	I:sample_driver_foo_isr: param=0x00147078 count=0
	I:monitor thread got data payload #0
	I:sample_driver_foo_isr: param=0x00147078 count=1
	I:monitor thread got data payload #1
	I:sample_driver_foo_isr: param=0x00147078 count=2
	I:monitor thread got data payload #2
	I:sample_driver_foo_isr: param=0x00147078 count=3
	I:monitor thread got data payload #3
	I:sample_driver_foo_isr: param=0x00147078 count=4
	I:monitor thread got data payload #4
	I:processing payload #1 complete
	I:writing processed data blob back to the sample device
	I:sample_driver_foo_isr: param=0x00147078 count=5
	I:monitor thread got data payload #5
	I:processing payload #2 complete
	I:writing processed data blob back to the sample device
	I:sample_driver_foo_isr: param=0x00147078 count=6
	I:monitor thread got data payload #6
	I:processing payload #3 complete
	I:writing processed data blob back to the sample device
	I:sample_driver_foo_isr: param=0x00147078 count=7
	I:monitor thread got data payload #7
	I:processing payload #4 complete
	I:writing processed data blob back to the sample device
	I:sample_driver_foo_isr: param=0x00147078 count=8
	I:monitor thread got data payload #8
	I:processing payload #5 complete
	I:writing processed data blob back to the sample device
	I:sample_driver_foo_isr: param=0x00147078 count=9
	I:monitor thread got data payload #9
	I:processing payload #6 complete
	I:writing processed data blob back to the sample device
	I:processing payload #7 complete
	I:writing processed data blob back to the sample device
	I:processing payload #8 complete
	I:writing processed data blob back to the sample device
	I:processing payload #9 complete
	I:writing processed data blob back to the sample device
	I:processing payload #10 complete
	I:writing processed data blob back to the sample device
	I:SUCCESS