I'm working with ARM Cortex-A9 in a Zynq7020 and having problem with software generated interrupts.
When I generate (writing to the ICDSGIR register) a SGI in core ARM1 it is only triggered once and not again, more writes to ICDSGIR does not trigger the interrupt.
Generating a SGI in core ARM0 sent to ARM1 works fine but not ARM1 to ARM1.
Is there any special handling needed for SGI in the ISR? What could I have missed in the configuration?
You probably should mark the end of interrupt by writing the interrupt ID along with the target processor to the ICCEOIR register:
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I am doing some bare metal C development on an ARM Cortex M3 SoC, and I wanted to check and see if it is possible to add a new user-defined interrupt handler to the NVIC. I am adding my own IRQ with the plan of triggering it via software, either via NVIC_SetPendingIRQ() or via the NVIC->STIR register. Neither seem to work.
I have added my interrupt vector name to the end of the vector list in the CMSIS startup assembler file, and added the corresponding enum to the system header, and while debugging and executing the function call NVIC_EnableIRQ(), it doesn't correctly update the NVIC->ISER (Interrupt Set Enable Register). So I guess, the question is, can you even add your own interrupt? There are 256 total interrupts than can be used in the ARM Cortex M3, and I just followed how the others were added so I figured it wouldn't be an issue.
Thank you.
The datasheet for your SoC should say how many interrupts are supported by the NVIC. While 240 is the maximum possible number for a Cortex-M3 device in general, the actual number on your chip is defined by the implementation and it makes sense to have that number be as small as possible to reduce costs.
In general, there is no way to add interrupts in software, but you might be able to use the SVCall interrupt, which is designed to be triggered by software. Or you could find some other interrupt you aren't using in your system, and which is not being activated by hardware, and try to use that for your purposes.
References:
Nested Vectored Interrupt Controller in the Cortex-M3 Devices Generic User Guide
The SVC instruction invokes the SVCall handler with an 8-bit service number available to the handler which can be used to invoke a handler from a look-up table (essentially a secondary vector table for software interrupts).
An example of that can be found at https://developer.arm.com/documentation/ka004005/latest, except there it uses a switch rather than a look-up table - to the same effect.
I'm using the std library. I don't know what the difference between I2C_FLAG_TXE and I2C_IT_TXE is.
Why when in interrupt function we don't use I2C_ClearFlag instead I2C_ClearITPendingBit? When do we used I2C_ClearFlag?
I'm starting learn stm32f4. I have very little experience.
I'm using the std library. I don't know what the difference between
I2C_FLAG_TXE and I2C_IT_TXE is.
From the processor point of view - the interrupt flag which has to be cleared by interrupt routine is set when the processor enters the interrupt.
Interrupt pending flag - indicates that the event which triggers the interrupt occurred but for some reason the interrupt routine has not been invoked yet.
It is good to know your hardware before using any libraries.
I'm trying to put a cortex m4 processor to sleep for a little less than a second. I want to be able to tell it to sleep, then a second later, or when a button is pressed, pick up right where I left off. I've looked in the reference manual and VLPS mode looks like it would fit my needs. I don't know how to begin to enter that mode or how to program the NVIC.
More Info:
I am doing this in C, on the bare metal.
You can download and inspect the code that implements this demo. Although the demo is for an RTOS the code used to place the CPU into a sleep mode is the same whether an RTOS is being used or the application is running on bare metal.
There are generic things you can do to place a Cortex-M3 core into a low power state (see the WFI instruction). To get extreme low power then you have to do chip specific things as well. The above linked code performs some chip specific pre-sleep processing (turn of peripherals, set the chips own sleep mode, etc.) before calling WFI, then does some chip specific things when it returns from the WFI instruction.
You don't need a RTOS in order to wake up from sleep a Cortex M4, what you need is to use and interrupt (ISR) you should refer to the manufacturer manual, you may wake up with a timer(ISR) or a button(GPIO) depending of the sleep-hibernation modes of your particular chip. Here is a ARM document more in depth about it.
http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dui0553a/BABGGICD.html
I'm writing a kernel (using qemu to simulate) for x86 as a school project and I ran into weird problem.
Even though I have set the interrupt flag in the eflags register, I'm sill not getting any clock interrupts (I checked with qemu info register command and I see eflag=0x292 which means it is set).
To be precise when I run a spin test (while(1); program) in user mode, I get one clock interrupt, but after that one, it stops, qemu does not seems to simulate more! did it happen to anyone else? Is there another mechanism that can affect interrupts?
Anyone have a clue?
Shai.
Apparently in x86, you have to acknowledge clock interrupts after each one.
I.e one must sent an acknowledgment to the lapic after every clock interrupt.
If you are expecting interrupts from the RTC, you must acknowledge the previous interrupt first by reading from REG_C (CMOS register 0x0C).
I am new to arm & have some doubs related to IRQ & FIQ. Please try to clarify these.
How many number of FIQ & IRQ channel arm have ?
And what number of handlers can we write for each channel ?
Also if we can register multiple handler for single interrupt channel how arm comes to know which handler to run.
The distinction between IRQ and FIQ goes right the way back to early days of ARM when it was designed by Acorn. It was always the case that the IRQ line was attached to an interrupt controller that multiplexed a large number of interrupt sources together. This is precisely what happens in all modern ARMs
The rationale behind the FIQ was to provide an extremely low latency response with maximum priority (it can safely pre-empt the IRQ handler). The comparatively large number of shadow registers facilitate writing handlers that store the handler's state in CPU registers and not hitting the stack.
The shadow registers are almost of the opposite set to those commonly used by APCS for function call, so writing handlers in C, would cause a push and eventual pop of up to 8 non-shadowed registers. Having any kind of interrupt demultiplexing wipes out any performance advantage that FIQ might have given.
All of this means that there is only really any benefit in using FIQ for very specialised applications where really hard-real time interrupt response is required for one interrupting device, and you're willing to write your handler in assembler. You'll also be left with working out how to synchronise with the rest of the system - some of which would rely on disabling IRQ to keep data synchronised.
traditionally the arm has one interrupt line which you can send to one of two handlers FIQ or IRQ. FIQ has a larger bank of FIQ mode only registers so you have fewer that you need to store on the stack. From there you read the vendor specific registers if any to determine the source of the interrupt and then branch into separate handlers.
More recently there have bend arm architectures with many interrupts 128, 256 each with a separate handler. So generically asking about arm is not as varied but about like asking something generic about x86.
All of this information is easily available in the ARM architectural reference manuals for the different architectures and the pinouts to the core (what the vendor builds its chip around) is documented in the technical reference manuals for the various cores (also very easy to obtain). infocenter.arm.com has the architecture and technical reference manuals as well as amba/axi (the data bus that the vendor connects to). Your question is completely answered in those documents.
The ARM processor directly supports only ONE IRQ and ONE FIQ. ARM supports multiple interrupts through a peripheral called Interrupt Controller. ARM standard interrupt controllers are called GIC (Generic Interrupt Controller).
The GIC has a number of inputs for peripherals to connect their interrupt lines and two output lines that connect to IRQ and FIQ. Basically it acts as a MUX. A GIC driver will setup configurations such as interrupt priority, type (IRQ/FIQ), masking etc.
In traditional ARM systems there is one entry each for IRQ and FIQ in the Exception Vectors. Depending on which line the interrupt fired, IRQ or FIQ handler is called. The interrupt handler queries the GIC (GIC CPU interface registers, to be specific) to get the interrupt number. Based on this interrupt number, corresponding device handler is invoked.
Number of interrupts depends on the specific GIC implementation. So you would have to check the manual for the interrupt controller in your system to get those specifics.
Note: The interrupt handling is slightly different depending on which specific ARM core you are coding for.
Actually the question is a bit tricky. You must specify in the question to which architecture in ARM you work. ARM v7-A and ARM v7-R Architecture Reference Manual (ARM ARM) specifies one FIQ and one IRQ, as many already answered. But ARMv7-M (used in Cortex-M processors) integrates a interrupt controller in the processor, and thus offers one NMI (instead of FIQ) and up to 240 IRQ lines.
For more information: ARMv7 A and ARMv7-R Architecure reference manual: http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0406c/index.html
ARMv7-M Architecture Reference Manual: http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.ddi0403e.b/index.html
As an example, Cortex M4 specs sheet: http://www.arm.com/products/processors/cortex-m/cortex-m4-processor.php