I have scoured the web, but haven't found a convincing answer to a couple of related questions I have, with regard to the "request_threaded_irq" feature.
Question1: Firstly, I was reading this article, regarding threaded IRQ's:
and there is this one line that isn't clear to me:
"Converting an interrupt to threaded makes only sense when the handler code takes advantage of it by integrating tasklet/softirq functionality and simplifying the locking."
I understand had we gone ahead with a "traditional", top half/bottom half approach, we would have needed either spin-locks or disable local IRQ to meddle with shared data. But, what I don't understand is, how would threaded interrupts simplify the need for locking by integrating tasklet/softirq functionality.
Question2: Secondly, what advantage (if any), does a request_threaded_handler approach have over a work_queue based bottom half approach ? In both cases it seems, as though the "work" is deferred to a dedicated thread. So, what is the difference ?
Question3: Lastly, in the following prototype:
int request_threaded_irq(unsigned int irq, irq_handler_t handler, irq_handler_t thread_fn, unsigned long irqflags, const char *devname, void *dev_id)
Is it possible that the "handler" part of the IRQ is continuously triggered by the relevant IRQ (say a UART receving characters at a high rate), even while the "thread_fn"(writing rx'd bytes to a circular buffer) part of the interrupt handler is busy processing IRQ's from previous wakeups ? So, wouldn't the handler be trying to "wakeup" an already running "thread_fn" ? How would the running irq thread_fn behave in that case ?
I would really appreciate if someone can help me understand this.