- How can I estimate the irq latency on ARM processor?
- What is the definition for irq latency?
You can find more information about it in ARM9E-S Core Technical Reference Manual:
There are three parts to interrupt latency:
Normally, the operating system won't have any influence over 1. The operating system certainly influences 2. For example, an operating system will sometimes disable interrupts [to avoid an interrupt interfering with some critical operation, such as for example modifying something to do with interrupt handling, or when scheduling a new task, or even when executing in an interrupt handler. Some operating systems may disable interrupts for several milliseconds, where a good realtime OS will not have interrupts disabled for more than microseconds at the most.
And of course, the time it takes from the first instruction in the interrupt handler runs, until the actual driver code or similar is running can be quite a few instructions, and the operating system is responsible for all of them.
For real time behaviour, it's often the "worst case" that matters, where in non-real time OS's, the overall execution time is much more important, so if it's quicker to not enable interrupts for a few hundred instructions, because it saves several instructions of "enable interrupts, then disable interrupts", a Linux or Windows type OS may well choose to do so.
Mats and Nemanja give some good information on interrupt latency. There
If a single core is processing interrupts, then when multiple interrupts occur at the same time, usually there is some resolution priority. However, interrupts are often disabled in the interrupt handler unless priority interrupt handling is enabled. So for example, a slow NAND flash IRQ is signaled and running and then an Ethernet interrupt occurs, it may be delayed until the NAND flash IRQ finishes. Of course, if you have priorty interrupts and you are concerned about the NAND flash interrupt, then things can actually be worse, if the Ethernet is given priority.
The second issue is when mainline code clears/sets the interrupt flag. Typically this is done with something like,
A very large interrupt latency can be introduced if that
The Cortex-A9 has lots of lock free instructions that can prevent this by never masking interrupts; because of better assembler instructions than
Finally, a lot of the technical discussions will assume zero-wait state RAM. It is likely that the cache will need to be filled and if you know your memory data rate (maybe 2-4 machine cycles), then the worst case code path would multiply by this.
Whether you have SMP interrupt handling, priority interrupts, and lock free main line depends on your kernel configuration and version; these are issues for the OS. Other issues are intrinsic to the CPU/SOC interrupt controller, and to the interrupt code itself.