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I would like to estimate the amount of opcodes it takes a ARM cortex A9 single core to handle an IRQ.

Assuming I work with Linux kernel 3.4, how many opcodes it takes to call the irq and execute the irq_handler ?

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Why opcodes? Do you mean instruction or clock cycles? –  Turbo J Feb 3 '13 at 18:14
    
Why do you ask? Isn't the admissible interrupt frequency, or the latency (from interrupt hardware impulse to start of handler either in the kernel or a signal handler in the application) more relevant? –  Basile Starynkevitch Feb 3 '13 at 18:23
    
@BillPringlemeir stackoverflow.com/questions/14698229/… please fill free to add topics to the question and answer it –  0x90 Feb 5 '13 at 0:31
    
@TurboJ can you specify the difference between opcodes and instructions? –  0x90 Feb 19 '13 at 4:40
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@0x90 An "opcode", operation code, is only the binary code to code a specific operation so that the CPU knows which operation to perform. The instruction is the opcode + the other bits encoding the parameters for example. –  Étienne Aug 10 '13 at 16:10

2 Answers 2

You question is related how to calculate the interrupt latency of Linux. At least you might be interested in how long it takes before your interrupt even starts. We will ignore this aspect of irqs here.

A simple way is to toggle a GPIO and use a scope to measure the interrupt. You may even toggle the GPIO multiple times to see the time different phases take. This Window CE link shows an example measuring for latency. Some interrupt controller (such as the IMX) have I/O multiplexing modes where an interrupt number will raise/lower a particular I/O line. Alternatively, you can add code to toggle the line (see below for routines).

The source for the primary interrupt handling is in entry-armv.S. There are macros defined for the interrupt controller you use and these depend on the .config file. For instance, there is pre-emptive interrupts, multi-interrupt controllers, SMP, etc. The primary vectors are defined at the bottom of entry-armv.S. The general gist is that the current operating mode is inspected and then either __irq_usr or __irq_svc is taken. These routines have a different pre-ample to store state, but they both end up calling the irq_handler macro. The _irq_usr has stuff about cmpxchg, but if you specify and ARM cortex in your .config, this won't apply. The main difference will be the possible context switch after the IRQ occurs in user mode. Your machine defines mach/entry-macro.S which are assembler macros to access the interrupt controller and get an interrupt number. It then jumps to generic irq handling code in the top level kernel directory.

So the second way would be to inspect the code and calculate it directly. This is probably easier if you look at the source, compile your kernel and then do an objdump --disassemble on the vmlinux image and look for these symbols. You will see the irq_handler macro expanded and it should jump to your IRQ code eventually.

As you can see from the source, there is also TRACE_IRQFLAGS. You can check to see if this is available on the Cortex A9 you are using with make menuconfig (and type /TRACE_IRQFLAGS). I don't know if it is available or not.

There are variations such as,

  1. Interrupt from User/SVC mode.
  2. Other interrupt currently running.
  3. Code that is interrupted (such as stm/ldm) may take some time to complete.
  4. Page faults in your ISR. Some Alsa drivers can fault with unallocated pages in at least some Linux versions.
  5. Conditionals in your ISR.

Measuring on a scope will show the jitter in IRQ servicing. Examining the instructions will generally show that the IRQ may never be serviced; for example if higher priority interrupts constantly pre-empt/prevent the IRQ. Probably you need to do both to fully optimize for a hard deadline.

Often you don't care how long the whole IRQ takes but the time between the IRQ line being raised and writing/reading some peripheral register. For instance, a FIFO may have limited depth and if the latency between the IRQ occurring and reading the FIFO register is greater than FIFO_Size x BPS, then you have issues with the FIFO overflowing.

The FIQ infra-structure is a lot faster, but the kernel facilities you can use are far less!

Edit: The Cortex A9 technical reference has instruction counts in appendix B. Most ARM instruction are a single cycle on most architectures, except memory load/store, multiples and branches. Follow the 3rd and 4th paragraphs above to find the complete instruction path to handle a Linux interrupt for your configuration and just add it up; for an estimate (as the original question asks) you can just count the instructions as they are generally a single cycle.

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Whilst you can calculate the theoretical minimum number of core cycles by inspection of the source code, the number actually taken is far less certain due to the effects of caching, memory and memory controller performance, what the other core is doing at the time and various other factors dependant on the micro-architecture of the ARM processor in question.

I suspect you would be better off measuring the actual interrupt latency performance of your system, either using a digital 'scope or performance counters.

Of course, for hard real-time applications, you need to know the worst case interrupt latency - which includes the worst case of all of these factors.

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Can you please explain in more detail, how to measure the worst case theoretically from source code? Thanks –  0x90 Feb 3 '13 at 23:52
    
I don't see any way of doing this without am accurate register-level simulation of the entire CPU and memory subsystem (e.g. of the design in Verilog or VHDL)- and a workload to run on it so that you can model the effects of various caches in the device. Again, I think you'd have to measure it and make some assumptions. –  marko Feb 3 '13 at 23:56
    
you surely can roughly bound it. if you can bound the number of particles in planet I think you can bound how an ARM cpu work in the best worst case –  0x90 Feb 4 '13 at 0:05
    
Absolutely - the difference is going to be a the odd cache miss here, and some memory latency there. I suspect we're looking at tenths of a micro-second. The Linux kernel is responsible for way more latency itself. What is going to be hard work is estimating these effects based on reference manuals and schematics for your system. –  marko Feb 4 '13 at 0:12
    
Worst case is all cache misses, isn't it? –  artless noise Feb 4 '13 at 1:19

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