According to the ARM IC.

In ARM state, the value of the PC is the address of the current instruction plus 8 bytes.

In Thumb state:

  • For B, BL, CBNZ, and CBZ instructions, the value of the PC is the address of the current instruction plus 4 bytes.
  • For all other instructions that use labels, the value of the PC is the address of the current instruction plus 4 bytes, with bit[1] of the result cleared to 0 to make it word-aligned.

Simply saying, the value of the PC register points to the instruction after the next instruction. This is the thing I don't get. Usually (particularly on the x86) program counter register is used to point to the address of the next instruction to be executed.

So, what are the premises underlying that? Conditional execution, maybe?

  • 1
    I'm sure someone more at home with the architecture can give a more detailed explanation, but in short; R15 contains the address of the next instruction to be fetched, due to prefetching it's (for arm state) 8 or in some cases 12 bytes ahead of the currently executing instruction. Jun 6, 2014 at 22:39
  • @JoachimIsaksson In which cases should the value of R15 be the address of the current instruction plus 12 bytes?
    – newbie
    Jun 19, 2014 at 17:04
  • @Notlikethat You can read RIP directly on x86-64: lea rax, [rip]. On x86-32, the most direct way is probably with a call instruction, which pushes EIP as the return address. It's nowhere near as exposed as it is on ARM, though, where it can be a src or dst for pretty much any instruction or addressing mode, IIRC. Jun 24, 2016 at 0:22
  • @Peter OK, I concede ;) I suppose I take "register" here to mean "something which can be an operand to an instruction", and my x86 knowledge kinda fades out beyond the 32-bit SSE2 era... Jun 24, 2016 at 9:12
  • A related thread: stackoverflow.com/questions/59404844/… Dec 20, 2019 at 2:05

2 Answers 2


It's a nasty bit of legacy abstraction leakage.

The original ARM design had a 3-stage pipeline (fetch-decode-execute). To simplify the design they chose to have the PC read as the value currently on the instruction fetch address lines, rather than that of the currently executing instruction from 2 cycles ago. Since most PC-relative addresses are calculated at link time, it's easier to have the assembler/linker compensate for that 2-instruction offset than to design all the logic to 'correct' the PC register.

Of course, that's all firmly on the "things that made sense 30 years ago" pile. Now imagine what it takes to keep a meaningful value in that register on today's 15+ stage, multiple-issue, out-of-order pipelines, and you might appreciate why it's hard to find a CPU designer these days who thinks exposing the PC as a register is a good idea.

Still, on the upside, at least it's not quite as horrible as delay slots. Instead, contrary to what you suppose, having every instruction execute conditionally was really just another optimisation around that prefetch offset. Rather than always having to take pipeline flush delays when branching around conditional code (or still executing whatever's left in the pipe like a crazy person), you can avoid very short branches entirely; the pipeline stays busy, and the decoded instructions can just execute as NOPs when the flags don't match*. Again, these days we have effective branch predictors and it ends up being more of a hindrance than a help, but for 1985 it was cool.

* "...the instruction set with the most NOPs on the planet."

  • 2
    Love your answer! May I ask you what do you think about the use of the least significant bit of the PC register to determine CPU state? Isn't that weird?
    – newbie
    Jun 7, 2014 at 1:16
  • 6
    @newbie It's not the lsb of the PC - that would cause an alignment fault - it's only the lsb of the target address of a bx, blx or bxj instruction that controls an instruction set switch. The current state is indicated in bit 5 of the CPSR. Jun 7, 2014 at 2:06
  • Oops! I know about alignment exceptions, but I was thinking that the lsb is just ignored when the PC register is actually fetched. It's clear now, thank you! :)
    – newbie
    Jun 7, 2014 at 2:28
  • 2
    I have wondered how many times ARM designers have cursed having to keep CPUs compatible with that old behavior. Also, as bad as delays slots are, the worst thing about them is how poorly documented they are, especially with how assemblers deal with them (assemblers often try to hide their existence from you, which seems to be the worst/most confusing thing to do in my opinion). Jun 14, 2014 at 22:12
  • 1
    @supercat On the early cores, Thumb state involved switching in what was more or less a separate bolted-on pre-decode stage which converted the Thumb encoding into the equivalent ARM encoding and fed it into the start of the regular ARM pipeline. Note "Thumb instruction controller", and that ARM7DMI (no T) was also a thing. The ARMv7 architecture (once Thumb-2 was commonplace) had a big cleanup and did redefine most writes to the PC to be interworking. Jul 27, 2016 at 21:44

that's true...

one example is below: C program:

int f,g,y;//global variables
int sum(int a, int b){
     return (a+b);
int main(void){
    f = 2;
    g = 3;
    y = sum(f, g);
    return y;

compile to assembly:

    00008390 <sum>:
int sum(int a, int b) {
return (a + b);
    8390: e0800001 add r0, r0, r1
    8394: e12fff1e bx lr
    00008398 <main>:
int f, g, y; // global variables
int sum(int a, int b);
int main(void) {
    8398: e92d4008 push {r3, lr}
f = 2;
    839c: e3a00002 mov r0, #2
    83a0: e59f301c ldr r3, [pc, #28] ; 83c4 <main+0x2c> 
    83a4: e5830000 str r0, [r3]
g = 3;
    83a8: e3a01003 mov r1, #3
    83ac: e59f3014 ldr r3, [pc, #20] ; 83c8 <main+0x30>
    83b0: e5831000 str r1, [r3]
y = sum(f,g);
    83b4: ebfffff5 bl 8390 <sum>
    83b8: e59f300c ldr r3, [pc, #12] ; 83cc <main+0x34>
    83bc: e5830000 str r0, [r3]
return y;
83c0: e8bd8008 pop {r3, pc}
83c4: 00010570 .word 0x00010570
83c8: 00010574 .word 0x00010574
83cc: 00010578 .word 0x00010578

see the above LDR's PC value--here is used to load variable f,g,y's address to r3.

    83a0: e59f301c ldr r3, [pc, #28];83c4 main+0x2c
    PC=0x83c4-28=0x83a8-0x1C = 0x83a8

PC's value is just the current executing instruction's next's next instruction. as ARM uses 32bits instruction, but it's using byte address, so + 8 means 8bytes, two instructions' length.

so attached ARM archi's 5 stage pipe linefetch, decode, execute, memory, writeback

ARM's 5 stage pipeline

the PC register is added by 4 each clock, so when instruction bubbled to execute--the current instruction, PC register's already 2 clock passed! now it's + 8. that actually means: PC points the "fetch" instruction, current instruction means "execute" instruction, so PC means the next next to be executed.

BTW: the pic is from Harris's book of Digital Design and Computer Architecture ARM Edition

  • 3
    the OP asked why it's like that, not if it is true or not
    – phuclv
    Apr 10, 2018 at 11:40

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