4

I'm doing a project in x86-64 NASM and came across the instruction:

mov rdi, rdi

in the output of a compiler my professor wrote.

I have searched all over but can't find mention of why this would be needed. Does it affect the flags or is it something clever that I don't understand?

To give some context it's present in a loop right before the same register is decremented with sub.

  • 4
    Is this code written by a human, and not compiler output? It's not mov (rdi), rdi or mov rdi, [rdi] right? – that other guy Mar 14 at 18:07
  • 2
    Probably just a codegen artifact then? Does it go away if you compile with -O1 or equivalent? – that other guy Mar 14 at 18:20
  • 1
    Its a compiler my professor wrote, I am optimising the output of some programs by hand – nrmad Mar 14 at 18:45
  • 3
    Wonder if your compiler used mov rdi, rdi as some form of NOP to align the beginning of the loop on a 16-byte boundary for performance reasons. Does this instruction exist inside the loop or is it just before the instruction at the top of the loop? It likely is an artifact of code generation as @thatotherguy suggested if your professors compiler doesn't do a good job of optimizing away unnecessary instructions. – Michael Petch Mar 14 at 18:56
  • 3
    I think your professor just hasn't implemented Move Elimination, the step in the compilation process that would normally optimize away redundant movs including this one. If this is homework, it may be an intentional omission because it's a simple thing for students to spot and fix by hand. – that other guy Mar 14 at 20:02
7

The instruction mov rdi, rdi is just an inefficient 3 byte NOP, equivalent to an actual NOP instruction. Assembling it, it generates the byte combination

48 89 ff       mov rdi, rdi

That can be considered as a NOP because it does neither affect the flags nor the registers. The only architectural effect is to advance the program counter to the next instruction.

It's common to use (multi-byte) NOPs to align the next instruction to a certain address, a popular example being an aligned jump target, especially at the top of a loop.

But in this case, it appears it's just an artifact of code-generation from a non-optimizing compiler, not being used for intentional padding.


It's inefficient compared to a true nop because it won't be special-cased to run more cheaply. (Its microarchitectural effect is different on current CPUs). It adds a cycle of latency to the dependency chain through RDI, and uses an ALU execution unit. (Neither Intel nor AMD CPUs can "eliminate" mov same,same and run it with zero latency in the register-rename stage, only between different architectural registers. mov rax,rdi for example can be about as cheap as a nop on IvyBridge+ and Ryzen, if you don't mind clobbering RAX.)

In your case, you should just remove it (instead of replacing it with 66 66 90 (short NOP with redundant operand-size prefixes) or 01 1F 00 (long NOP), because it's not being used for padding.

  • It's not "fancy", it's horrible. It's architecturally a NOP, but microarchitecturally introduces a cycle of latency in the critical path for RDI. It's really stupid vs. db 0x66, 0x66, 0x90 or something, or tacking on a redundant DS or SS prefix to other instructions and avoiding a separate NOP. – Peter Cordes Mar 14 at 20:48
  • 3
    @PeterCordes in this case interesting, that in x86 windows DLLs, may be 50%+ functions begin with mov edi,edi instruction. some of this used for hot patch (before function begin exist 5 or more int 3 or nop) but many functions anyway begin with mov edi,edi despite no 5 bytes unused space before function begin. but this is only in 32-bit code. in x64 I not view mov rdi,rdi instructions – RbMm Mar 14 at 22:14
  • @RbMm: edi is a call-preserved register, so tiny functions are potentially hurting their caller by doing this, if there's a bottleneck involving a dep chain through EDI. But for any larger function, the cost of the function body will hide that latency. Still, mov eax, ecx would be a better choice. EAX is always "dead" at that point (call-clobbered and not holding a function arg), and using different registers allow Intel IvB+ and AMD Zen to eliminate the mov. – Peter Cordes Mar 14 at 23:20
  • 1
    @Peter, Intel and AMD both recommend 0f 1f 00 for a 3-byte no-op. – prl Mar 15 at 2:07
  • 1

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.