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Another device-driver?

Another device-driver?. Getting ready to program the network interface. Inexpensive NIC: $8.95. RealTek 8139 processor. ConnectGear D30-TX (Made in China). Hardware components. main memory. packet. nic. TX FIFO. transceiver. buffer. LAN cable. B U S. RX FIFO. CPU.

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Another device-driver?

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  1. Another device-driver? Getting ready to program the network interface

  2. Inexpensive NIC: $8.95 RealTek 8139 processor ConnectGear D30-TX (Made in China)

  3. Hardware components main memory packet nic TX FIFO transceiver buffer LAN cable B U S RX FIFO CPU

  4. PC-to-PC connection PC PC NIC NIC RJ-45 connector RJ-45 connector UTP Category-5 “crossover” cable

  5. Kudlick Classroom’s stations 8 9 10 15 16 17 18 19 20 28 29 30 4 5 6 7 11 12 13 14 24 25 26 27 1 2 3 21 22 23 LECTERN

  6. In-class exercise #1 • A network device-driver will need to know certain identifying information about the workstation it is running on -- so it can let other stations know to whom they should send their reply-messages • Our ‘utsinfo.c’ module shows how kernel code can find out the name of the ‘node’ on which it is executing • Try it out – then study its code to use later

  7. Some NIC characteristics • With our previous device-driver examples (e.g., dram, vram, and hd), the data to be read was already there waiting to be read • But with a network interface card (NIC), we may want to read its data before any data has arrived from other workstations • In such cases we would like to wait until data arrives rather than abandon reading

  8. Could do ‘busy waiting’? • It is possible for a network driver to ‘poll’ a status-bit continuously until data is ready (as we did with the IDE Controller’s status) • This is called ‘busy waiting’ – it could take up a lot of valuable time before any benefit is realized • In a multitasking system we want to avoid ‘busy waiting’ whenever possible!

  9. Alternative is ‘blocking’ • If trying to read from device-files when no data is present, but new data is expected to arrive, the system can ‘block’ the task from consuming valuable CPU time while it waits, by ‘putting the task to sleep’ and arranging for it to be ‘awakened’ as soon as some new data has actually arrived

  10. What does ‘sleep’ mean? • The Linux kernel puts a task to sleep by simply modifying the value of its ‘state’ variable: • TASK_RUNNING • TASK_STOPPED • TASK_UNINTERRUPTIBLE • TASK_INTERRUPTIBLE • Only tasks with ‘state == TASK_RUNNING’ are scheduled to be granted time on the CPU

  11. What does ‘wakeup’ mean? • A sleeping task is one whose ‘task.state’ is equal to ‘TASK_INTERRUPTIBLE’ or to ‘TASK_UNINTERRUPTIBLE’ • A sleeping task is ‘woken up’ by changing its ‘task,state’ to be ‘TASK_RUNNING’ • When the Linux scheduler sees that a task is in the ‘TASK_RUNNING’ state, it grants that task some CPU time for execution

  12. ‘run’ queues and ‘wait’ queues • In order for Linux to efficiently manage the scheduling of the various tasks, separate queues are maintained for ‘running’ tasks and for tasks that are asleep while waiting for a particular event to occur (such as the arrival of new data from the network)

  13. Some tasks are ‘ready-to-run’

  14. Kernel support-routines • The Linux kernel makes it easy for drivers to perform the ‘sleep’ and ‘wakeup’ actions while avoiding potential ‘race conditions’ which are inherent in a ‘preemptive’ kernel that might be running on multiple CPUs

  15. Use of Linux wait-queues • #include <linux/sched.h> • wait_queue_head_t my_queue; • init_waitqueue_head( &my_queue ); • sleep_on( &my_queue ); • wake_up( &my_queue ); • But can’t unload driver if task stays asleep!

  16. Kernel waitqueues waitqueue waitqueue waitqueue waitqueue

  17. ‘interruptible’ is preferred #include <linux/sched.h> wait_queue_head_t wq; init_waitqueue_head( &wq ); wait_event_interruptible( wq, <condition> ); wake_up_interruptible( &wq ); An ‘interruptible’ sleep can awoken by a signal -- -- in case you might want to ‘unload’ your driver!

  18. A convenient ‘macro’ • DECLARE_WAIT_QUEUE_HEAD( wq ); • This statement can be placed outside your module’s functions (i.e., a ‘global’ object) • It combines declaration with initialization: wait_queue_head_t wq; init_waitqueue_head( &wq );

  19. A character device: ‘stash’ • Device works like a public ‘clipboard’ • It uses kernel memory to store its data • It allows ‘communication’ between tasks • What one task writes, another can read!

  20. Ringbuffer • A first-in first-out data-structure (FIFO) • Uses a storage array of finite length • Uses two array-indices: ‘head’ and ‘tail’ • Data is added at the current ‘tail’ position • Data is removed from the ‘head’ position

  21. Ringbuffer (continued) • One array-position is always left unused • Condition ‘head == tail’ means “empty” • Condition tail == head-1 means “full” • Both ‘head’ and ‘tail’ will “wraparound” • Calculation: next = ( next+1 )%RINGSIZE;

  22. read-algorithm for ‘stash’ • if ( ringbuffer_is_empty ) { // sleep, until another task supplies some data // or else exit if a signal is received by this task } • Remove a byte from the ringbuffer; • Copy the byte to user-space; • Awaken any sleeping writers; • return 1;

  23. write-algorithm for ‘stash’ • if ( ringbuffer_is_full ) { // sleep, until some data is removed by another task // or else exit if a signal is received by this task } • Copy a byte from user-space; • Insert this byte into ringbuffer; • Awaken any sleeping readers; • return 1;

  24. Demonstration of ‘stash’ • Quick demo: we can use I/O redirection • For demonstrating ‘write’ to /dev/stash: $ echo “Hello” > /dev/stash • For demonstrating ‘read’ from /dev/stash: $ cat /dev/stash

  25. The ‘device’ file-node • We cannot use the ‘stash.c’ device-driver until a device-node has been created that allows both ‘read’ and ‘write’ access (the SysAdmin must do this setup for us): #root mknod /dev/stash c 40 0 #root chmod a+rw /dev/stash • You can try using the ‘sudo’ command to these steps (if that privilege was granted)

  26. Alternative: use ‘/dev/foo’ • If you cannot create the ‘/dev/stash’ node, you can use an existing ‘generic’ node if you change the driver’s ‘major’ number and the device-name you register it with • Use the command: $ ls –l /dev/foo to find out what major number you must use

  27. In-class exercise #2 • Add a ‘get_info()’ function to this driver to create a pseudo-file (named ‘/proc/stash’) that will show the current contents of the ringbuffer (if any) and the current values for the ‘head’ and ‘tail’ buffer-indices • Don’t forget: use ‘create_proc_info_entry()’ in your ‘init_module()’ function, and call ‘remove_proc_entry()’ during ‘cleanup’

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