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On using ‘tasklets’

On using ‘tasklets’. An example of the Linux kernel’s ‘tasklet’ mechanism for deferring some interrupt-handling work. Recall purpose of Project #2. Allow you to gain experience encountering the kinds of issues that commonly arise in crafting software to operate real hardware:

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On using ‘tasklets’

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  1. On using ‘tasklets’ An example of the Linux kernel’s ‘tasklet’ mechanism for deferring some interrupt-handling work

  2. Recall purpose of Project #2 • Allow you to gain experience encountering the kinds of issues that commonly arise in crafting software to operate real hardware: • Learning the hardware device’s capabilities • Deciding which driver-methods to implement • Accommodating your platform’s interfaces • Exploiting the OS kernel’s support-functions • Devising a strategy for testing and debugging

  3. Driver enhancements • Now that you’ve had an opportunity to get acquainted with the NS16550 serial UART (its documented capabilities and its quirks) we can build upon what you experienced to contemplate software enhancements that might not have made much sense if you lacked any actual confrontation with ‘real-world’ peripheral hardware on PCs

  4. Urgent versus non-urgent • When some peripheral device issues an interrupt request, it may need a prompt response to handle an urgent situation • After the emergency has been dealt with, there may also be some further actions which are necessary, but which can be safely delayed without jeopardizing the integrity of proper system functioning

  5. The serial UART • As an example, when the UART receives characters via its serial-port, there is only a limited capability for preserving them in the device’s on-board ‘receive buffer’ • These received characters need to be quickly moved out of the UART before they get overwritten by newer data -- or before they can cause other incoming characters to be ‘lost’ for lack of space

  6. The ‘handshake’ lines • A device-driver for the UART can use the handshaking signal-lines to regulate the quantity of data being transmitted to it • It can de-assert the ‘Clear-To-Send’ signal being sampled by its equipment partner as a way to temporarily pause data-transfers • Once the incoming data-stream is paused, there is less urgency to move data aside

  7. 9-wire null-modem cable CD CD RxD RxD TxD TxD GND GND DSR DSR DTR DTR RTS RTS CTS CTS RI RI Data Terminal Equipment Data Terminal Equipment the sender the receiver

  8. Modem Control Register 7 6 5 4 3 2 1 0 0 0 0 LOOP BACK OUT2 OUT1 RTS DTR The receiver clears this bit Legend: DTR = Data Terminal Ready (1=yes, 0=no) RTS = Request To Send (1=yes, 0=no) OUT1 = not used (except in loopback mode) OUT2 = enables the UART to issue interrupts LOOPBACK-mode (1=enabled, 0=disabled)

  9. Modem Status Register The sender checks this bit 7 6 5 4 3 2 1 0 DCD RI DSR CTS delta DCD delta RI delta DSR delta CTS set if the corresponding bit has changed since the last time this register was read Legend: [---- loopback-mode ----] CTS = Clear To Send (1=yes, 0=no) [bit 0 in Modem Control] DSR = Data Set Ready (1=yes, 0=no) [bit 1 in Modem Control] RI = Ring Indicator (1=yes,0=no) [bit 2 in Modem Control] DCD = Data Carrier Detected (1=yes,0=no) [bit 3 in Modem Control]

  10. The sender’s algorithm Set RTS=1 in the Modem Control Register Read the Modem Status Register CTS==1? NO YES Read the Line Status Register THRE==1? NO YES Write byte to the Transmit Data Register DONE

  11. The receiver’s actions • When the receiver’s storage capacity has been reached, it takes urgentaction to ‘pause’ any further transfers of data (i.e., it writes ‘0’ to the RTS-bit in its Modem Control register) • Then it needs to remove its accumulation of received data out of its storage medium • Being less urgent this can be postponed

  12. Interrupt handling • Often it’s beneficial to separate the actions a driver performs in responding to a device interrupt-request into two categories: the urgent ones are performed immediately, the less urgent ones temporarily delayed • Accordingly programmers write separate functions, known as the “top half” and the “bottom half” for an interrupt handler

  13. Application to the UART • Top Half: • Tell sender to ‘pause’ further data-transfers • Bottom-Half: • Move accumulated data out of the device’s on-board storage-area (e.g., its receive FIFO)

  14. A tasklet for ‘bottom half’ work • Your device-driver allocates and initializes a ‘struct tasklet_struct’ object, possessing a name, a function and a pointer to data • Your driver’s ‘top-half’ interrupt-handler will schedule your tasklet for future execution name function ‘struct tasklet_struct’ object data-pointer

  15. Linux syntax • #include <linux/interrupt.h> • struct tasklet_struct my_tasklet; • struct mydata { … } my_tasklet_data; • void my_function ( unsigned long ); • tasklet_init( &my_tasklet, &my_function, (unsigned long)&my_tasklet_data ); • tasklet_schedule( &my_tasklet ); • tasklet_kill( &my_tasklet );

  16. Tasklet semantics • A few technical points to keep in mind if you decide to make use of ‘tasklets’: • A ‘tasklet’ runs at ‘interrupt time’ (so it doesn’t own any user-space context, just kernel-space context) The kernel-space context is consistent across all tasks kernel space user space Some interrupted task’s context resides here (so it can’t be predicted) ‘virtual’ memory

  17. More tasklet semantics… • A tasklet runs in ‘atomic mode’ (so cannot sleep), although it can ‘wake up’ a task that is sleeping • A tasklet executes on the CPU that scheduled it (and so doesn’t execute concurrently with itself) • You can schedule your tasklet to run either at “normal” priority or at “high” priority – the latter ones all are run before any of the former ones

  18. ‘sleep’ versus ‘busy waiting’ • Our ‘tasklet.c’ demo uses the ‘interruptible sleep’ mechanism in its device-driver ‘read()’ method • Whenever the UART receives new data, it will interrupt whatever else the CPU is doing • Quickly our ‘top half’ interrupt-handler pauses any more data-transfers, schedules our ‘bottom half’ for future execution, then resumes the interrupted task • Later our ‘tasklet’ will move accumulated data from the FIFO to a ringbuffer, then will awaken any task was sleeping on our ‘read’ function’s wait-queue

  19. The senario overview READ() sleeps until driver’s ringbuffer has some data moves data from driver’s ringbuffer to user’s buffer issues ‘Clear-To-Send’ if case the driver’s ringbuffer has been emptied reports count of bytes returned in user’s buffer Arrival of new data interrupts the CPU ISR stops the sending of additional data schedules the tasklet resumes the Interrupted task TASKLET transfers received bytes from UART to to ringbuffer wakes up sleeping readers

  20. ‘write()’ • We did not employ efficiency-techniques in our device-driver’s ‘write()’ function: • No wait-queues • No interrupts • No tasklets • Thus there is still an opportunity for you to add improvements to our ‘tasklet.c’ demo!

  21. In-class exercise • Download our ‘tasklet.c’ module from the course website, compile it, and install it a pair of our machines which are connected to each other via a null-modem cable • Try testing the ‘robustness’ of our driver: First launch the ‘cat’ command … … then redirect lots of screen-output! $ cat /dev/uart $ ls -l /usr/bin > /dev/uart

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