7

I am learning ARM Assembly, and I am stuck on something right now.

I know about the Link Register, which if I'm not wrong holds the address to return to when a function call completes.

So if we have something like that (taken from the ARM documentation):

0 | here
1 |   B there
2 |   
3 |   CMP R1, #0
4 |   BEQ anotherfunc
5 |
6 |   BL sub+rom ;  Call subroutine at computed address.

So, if we think of the column at the left as addresses of each instruction, then after the B there at address 1, the Link Register holds the value of 1 right?

Then the program goes to the method there and then it uses the value of the Link Register to know where to return.

If we skip to address 6 now, where I am stuck, we know what BL copies the address of the next instruction into lr (r14, the link register).

So now it would copy the address of sub which is a subroutine (what is a subroutine??) + rom (which is a number?) or the address of sub+rom (I don't know what this could be).

But in general, when would we need BL? Why do we want it in the example above? Can someone give me an example where we would really need it?

Thanks!

1
  • "when would we need BL?" If you write a function that can be called from more than one place it will need to know to where it's supposed to return, which is what the link register is used for. And to set the link register to the correct address to return to you use the BL instruction.
    – Michael
    Dec 4 '15 at 15:40
33

It seems there is a bit of confusion. Here is an explanation :

The B instruction will branch. It jumps to another instruction, and there is no return expected. The Link Register (LR) is not touched.

The BL instruction will branch, but also link. LR will be loaded with the address of the instruction after BL in memory, not the instruction executed after BL. It will then be possible to return from the branch using LR.

Example :

start:
01:  MOV r0, r2     ; some instruction
02:  B there        ; go there and never return !

there:
11:  MOV r1, r0         ; some instruction
12:  BL some_function   ; go to some_function, but hope to return !
                        ; this BL will load 13 into LR
13:  MOV r5, r0
14:  BL some_function   ; this BL will load 15 into LR
15:  MOV r6, r0


some_function:
     MOV r0, #3
     B LR               ; here, we go back to where we were before

If you want to call another function inside a function, LR will be overwritten, so you won't be able to return. The common solution is to save LR on the stack with PUSH {LR}, and restore it before returning with POP {LR}. You can even restore and return in a single POP {PC} : this will restore the value of LR, but in the program counter, effectively returning of the function.

12
  • The called subroutine may store the link register on the stack, in which case, it can return by moving from the stack to PC (R15). Unlike subroutines, some exceptions result in LR pointing to the instruction that caused the exception, as opposed to what would be a return address.
    – rcgldr
    Dec 4 '15 at 16:39
  • @rcgldr About the exceptions, they work just like interrupts, and they actually store the return address to LR, and thus you can return from exceptions. The instruction that caused the exception is the instruction just before.
    – ElderBug
    Dec 4 '15 at 16:41
  • 2
    @rcgldr Okay I found it, and you are right : "The actual location pointed to by the program counter when an exception is taken depends on the exception type. The return address may not necessarily be the next instruction pointed to by the program counter." But it is still a return address that can be used to return.
    – ElderBug
    Dec 4 '15 at 16:49
  • 1
    @PeterCordes Poping into PC is weird (but convenient), but I learned that you can also ADD, SUB or even AND (and plenty others) into PC, like AND pc, pc, r2 (edit: actually deprecated). About your check on godbolt ... Actually, r3 isn't even the stack pointer (it is sp, alias r13). I have no idea why GCC push r3. By convention r3 is volatile. If you use foo(int i) and return i;, it uses r4 (not volatile), which make sense.
    – ElderBug
    Dec 4 '15 at 18:04
  • 1
    @ElderBug: I think I know why gcc pushes a scratch reg along with lr, for my test code: It's keeping the stack aligned to an 8B boundary. Also interesting: stackoverflow.com/questions/27693979/… Dec 4 '15 at 19:03

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