The code following is the first part of u-boot to define interrupt vector table, and my question is how every line will be used. I understand the first 2 lines which is the starting point and the first instruction to implement: reset, and we define reset below. But when will we use these instructions below? According to System.map, every instruction has a fixed address, so _fiq is at 0x0000001C, when we want to execute fiq, we will copy this address into pc and then execute,right? But in which way can we jump to this instruction: ldr pc, _fiq? It's realised by hardware or software? Hope I make myself understood correctly.

>.globl _start  
>_start:b         reset  
>       ldr       pc, _undefined_instruction  
>       ldr       pc, _software_interrupt  
>       ldr       pc, _prefetch_abort  
>       ldr       pc, _data_abort  
>       ldr       pc, _not_used  
>       ldr       pc, _irq  
>       ldr       pc, _fiq  

>_undefined_instruction: .word undefined_instruction  
>_software_interrupt:    .word software_interrupt  
>_prefetch_abort:        .word prefetch_abort  
>_data_abort:            .word data_abort  
>_not_used:              .word not_used  
>_irq:                   .word irq  
>_fiq:                   .word fiq  
  • A further thinking: we first prepare every interrupt here, then start from "start" or "reset" computer, which are also defined as an interrupt. Then we continue the routine of reset. The following interrupts are only a preparation for future hardware/software interrupt. right?
    – user2122968
    Jan 23, 2014 at 16:21
  • ldr pc, _fiq is translated as ldr pc, [pc, #_fiq-offset]. So the word value at _fiq is loaded into the PC. Ie, you put a function pointer at the address _fiq. To begin with it will be NULL; later people can populate it. Interrupts are not enabled in u-boot by default. See: Enabling interrupts in u-boot on ARM. Jan 23, 2014 at 19:05

2 Answers 2


If you understand reset then you understand all of them.

When the processor is reset then hardware sets the pc to 0x0000 and starts executing by fetching the instruction at 0x0000. When an undefined instruction is executed or tries to be executed the hardware responds by setting the pc to 0x0004 and starts executing the instruction at 0x0004. irq interrupt, the hardware finishes the instruction it is executing starts executing the instruction at address 0x0018. and so on.

00000000 <_start>:
   0:   ea00000d    b   3c <reset>
   4:   e59ff014    ldr pc, [pc, #20]   ; 20 <_undefined_instruction>
   8:   e59ff014    ldr pc, [pc, #20]   ; 24 <_software_interrupt>
   c:   e59ff014    ldr pc, [pc, #20]   ; 28 <_prefetch_abort>
  10:   e59ff014    ldr pc, [pc, #20]   ; 2c <_data_abort>
  14:   e59ff014    ldr pc, [pc, #20]   ; 30 <_not_used>
  18:   e59ff014    ldr pc, [pc, #20]   ; 34 <_irq>
  1c:   e59ff014    ldr pc, [pc, #20]   ; 38 <_fiq>

00000020 <_undefined_instruction>:
  20:   00000000    andeq   r0, r0, r0

00000024 <_software_interrupt>:
  24:   00000000    andeq   r0, r0, r0

00000028 <_prefetch_abort>:
  28:   00000000    andeq   r0, r0, r0

0000002c <_data_abort>:
  2c:   00000000    andeq   r0, r0, r0

00000030 <_not_used>:
  30:   00000000    andeq   r0, r0, r0

00000034 <_irq>:
  34:   00000000    andeq   r0, r0, r0

00000038 <_fiq>:
  38:   00000000    andeq   r0, r0, r0

Now of course in addition to changing the pc and starting execution from these addresses. The hardware will save the state of the machine, switch processor modes if necessary and then start executing at the new address from the vector table.

Our job as programmers is to build the binary such that the instructions we want to be run for each of these instructions is at the right address. The hardware provides one word, one instruction for each location. Now if you never expect to ever have any of these exceptions, you dont have to have a branch at address zero for example you can just have your program start, there is nothing magic about the memory at these addresses. If you expect to have these exceptions, then you have two choices for instructions that are one word and can jump out of the way of the exception that follows. One is a branch the other is a load pc. There are pros and cons to each.

  • From what I see in specs for vector table at 0x0 resides initial SP value, is PC is set to 0x0 on reset how does processor interpret this value? Is it always an invalid instruction?
    – pbn
    Mar 22, 2017 at 11:08
  • 3
    you are confusing cortex-m with regular arm cores. regular arm cores are like above they execute the instruction at the address in the exception table. the cortex-m cores it is a vector table with the zero vector being the load value for the stack pointer, and offset 4 the reset vector on reset it loads the stack pointer from the vector table then starts execution at the reset vector address
    – old_timer
    Mar 22, 2017 at 14:12

When the hardware takes an exception, the program counter (PC) is automatically set to the address of the relevant exception vector and the processor begins executing instructions from that address. When the processor comes out of reset, the PC is automatically set to base+0. An undefined instruction sets the PC to base+4, etc. The base address of the vector table (base) is either 0x00000000, 0xFFFF0000, or VBAR depending on the processor and configuration. Note that this provides limited flexibility in where the vector table gets placed and you'll need to consult the ARM documentation in conjunction with the reference manual for the device that you are using to get the right value to be used.

The layout of the table (4 bytes per exception) makes it necessary to immediately branch from the vector to the actual exception handler. The reasons for the LDR PC, label approach are twofold - because a PC-relative branch is limited to (24 << 2) bits (+/-32MB) using B would constrain the layout of the code in memory somewhat; by loading an absolute address the handler can be located anywhere in memory. Secondly it makes it very simple to change exception handlers at runtime, by simply writing a different address to that location, rather than having to assemble and hotpatch a branch instruction.

There's little value to having a remappable reset vector in this way, however, which is why you tend to see that one implemented as a simple branch to skip over the rest of the vectors to the real entry point code.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.