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ARM Processor Modes

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Last time we discussed how ARM Processor interrupts work, and we mentioned that interrupts switch the processor from user mode to an operating system mode, but we never discussed what exactly the ARM Processor modes are. In this article we will discuss the ARM Processor modes, why they exist and when they are used.

The available processor modes vary by ARM model, so we will look at those commonly available. For the exact details on any specific ARM processor you need to check in that processor’s reference manual.

ARM Processor Modes

The purpose of processor modes is to regulate access to memory and hardware resources so that a process initiated by a specific user can’t access the memory of other processes or access hardware they don’t have permission for. The operating system can add quite refined permissions, so users only have access to certain files, read-only access to certain files, or other granular rights. This might all sound like overkill for a Raspberry Pi, but all versions of Linux, including Raspbian support multiple users and multiple processes all logged in and running at once. Further you might set up specific users and groups to grant the exact rights to processes like web servers to help protect you system from malicious hackers or program bugs causing havoc.

Most ARM processors have two security levels for processes. PL0 is for user mode programs and then PL1 is for operating system code. Newer ARM processors used in servers have a third level PL2 for virtualization hypervisors, so they can keep their various hosted operating systems completely separate. There is also an optional ARM build for secure computing, if this is present then there is an even higher PL3 level that is used for a system security monitor.

The following table from the ARM Processor Reference manual. There are quite a few processor modes and we’ll talk about them all, but the two main ones are user mode for regular programs and then system mode for the operating system.

Let’s list all the processor modes and describe what it is used for:

  • User – regular programs that can access the resources they have permission for.
  • FIQ – the processor goes into this mode when handling as fast interrupt. The operating system provides this code and it has access to all operating system resources.
  • IRQ – the processor goes into this mode when handling a regular interrupt. The operating system provides this code and it has access to all operating system resources.
  • Supervisor – when a user mode program makes an SVC Assembly instruction which calls an operating system services, the program switches to this mode, which allows the program to operate at a privileged level for the duration of the code.
  • Monitor – if you have an ARM processor with security extensions then this mode is used to monitor the system.
  • Abort – if a user mode program tries to access memory it isn’t allowed, then this mode is entered to let the operating system intervene and either terminate the program, or send the program a signal.
  • Hyp – this is hypervisor mode that is an optional ARM extension. This allows the virtual hypervisor run at a more secure level than the operating systems it is virtualizing.
  • Undefined – is a user mode program tries to execute an undefined or illegal Assembly instruction then this mode is entered and the operating system can terminate the program or send it a signal.
  • System – this is the mode that the operating system runs at. Processes that the operating system considers part of itself run at this level.

The mode bits in the table, are the bits that are set in the Control Program Status Register (CPSR) are the bits that get set in the lower order bits. This way the operating system can see what mode it’s in and act accordingly when appropriate.

ARM Boot Process

When powered on, the ARM processor starts up by initiating a reset interrupt. This causes the reset interrupt handler code to execute, which will typically be a branch to the code to start the operating system. At this point we are running in IRQ mode. We will change the processor mode to supervisor and initiate the operating system boot process. To change the processor mode we directly manipulate the bits in the CPSR with code like:

MRS   R0, CPSR        @ Move the CPSR to R0
BIC   R0, R0, #0x1F   @ clear the mode bits
ORR   R0, R0, #0x13   @ Set the mode bits to 10011 (SVC mode)
MSR   CPSR, R0        @ Update the CPSR

Note that reading and writing the CPSR like this are privileged instructions and only available to programs running in PL1 or better. Besides updating the processor mode, the operating system uses these to save a program’s state when doing multitasking. Saving the registers is easy, but the CPSR must also be preserved so as not to disrupt the running process.


This was a quick introduction to the ARM Processor modes. You don’t need to know this for application programming, but if you are interested in writing an operating system or if you are interested in how operating system support works for the ARM processor then this is a starting point.

If you are interested in learning more about ARM Assembly Language Programming, please check out my book, the details are available here.

Written by smist08

December 2, 2019 at 12:37 pm

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