As it is widely advertised, modern x86_64 processors have 64-bit registers that can be used in backward-compatible fashion as 32-bit registers, 16-bit registers and even 8-bit registers, for example:

  ================ rax (64 bits)
          ======== eax (32 bits)
              ====  ax (16 bits)
              ==    ah (8 bits)
                ==  al (8 bits)

Such a scheme may be taken literally, i.e. one can always access only the part of the register using a designated name for reading or writing purposes, and it would be highly logical. In fact, this is true for everything up to 32-bit:

mov  eax, 0x11112222 ; eax = 0x11112222
mov  ax, 0x3333      ; eax = 0x11113333 (works, only low 16 bits changed)
mov  al, 0x44        ; eax = 0x11113344 (works, only low 8 bits changed)
mov  ah, 0x55        ; eax = 0x11115544 (works, only high 8 bits changed)
xor  ah, ah          ; eax = 0x11110044 (works, only high 8 bits cleared)
mov  eax, 0x11112222 ; eax = 0x11112222
xor  al, al          ; eax = 0x11112200 (works, only low 8 bits cleared)
mov  eax, 0x11112222 ; eax = 0x11112222
xor  ax, ax          ; eax = 0x11110000 (works, only low 16 bits cleared)

However, things seem to be fairly awkward as soon as we get to 64-bit stuff:

mov  rax, 0x1111222233334444 ;           rax = 0x1111222233334444
mov  eax, 0x55556666         ; actual:   rax = 0x0000000055556666
                             ; expected: rax = 0x1111222255556666
                             ; upper 32 bits seem to be lost!
mov  rax, 0x1111222233334444 ;           rax = 0x1111222233334444
mov  ax, 0x7777              ;           rax = 0x1111222233337777 (works!)
mov  rax, 0x1111222233334444 ;           rax = 0x1111222233334444
xor  eax, eax                ; actual:   rax = 0x0000000000000000
                             ; expected: rax = 0x1111222200000000
                             ; again, it wiped whole register

Such behavior seems to be highly ridiculous and illogical to me. It looks like trying to write anything at all to eax by any means leads to wiping of high 32 bits of rax register.

So, I have 2 questions:

  1. I believe that this awkward behavior must be documented somewhere, but I can't seem to find detailed explanation (of how exactly high 32 bits of 64-bit register get wiped) anywhere. Am I right that writing to eax always wipes rax, or it's something more complicated? Does it apply to all 64-bit registers, or there are some exceptions?

    A strongly related question mentions the same behavior, but, alas, there are again no exact references to documentation.

    In other words, I'd like a link to documentation that specifies this behavior.

  2. Is it just me or this whole thing seems to be really weird and illogical (i.e. eax-ax-ah-al, rax-ax-ah-al having one behavior and rax-eax having another)? May be I'm missing some kind of vital point here on why was it implemented like that?

    An explanation on "why" would be highly appreciated.


1 Answer 1


The processor model as documented in the Intel/AMD processor manual is a pretty imperfect model for the real execution engine of a modern core. In particular, the notion of the processor registers does not match reality, there is no such thing as a EAX or RAX register.

One primary job of the instruction decoder is to convert the legacy x86/x64 instructions into micro-ops, instructions of a RISC-like processor. Small instructions that are easy to execute concurrently and being able to take advantage of multiple execution sub-units. Allowing as many as 6 instructions to execute at the same time.

To make that work, the notion of processor registers is virtualized as well. The instruction decoder allocates a register from a big bank of registers. When the instruction is retired, the value of that dynamically allocated register is written back to whatever register currently holds the value of, say, RAX.

To make that work smoothly and efficiently, allowing many instructions to execute concurrently, it is very important that these operations don't have an interdependency. And the worst kind you can have is that the register value depends on other instructions. The EFLAGS register is notorious, many instructions modify it.

Same problem with the way you like it to work. Big problem, it requires two register values to be merged when the instruction is retired. Creating a data dependency that's going to clog up the core. By forcing the upper 32-bit to 0, that dependency instantly disappears, no longer a need to merge. Warp 9 execution speed.

  • 11
    I'd like to see this answer merged in with the 'root' of the duplicate. It's a very nice perspective that helps explain the design choice.
    – MicroVirus
    Aug 23, 2014 at 9:39
  • 3
    Microarchitectures with a physical register file (e.g. Intel SnB-family, and AMD) write results to physical registers earlier than retirement. I think that part of your answer is probably only correct for Intel's P6 family (ppro to nehalem), which holds temporary results by value inside the ROB, instead of by references to physical registers. (P6 has register read stalls when reading too many not-recently-written registers. SnB removes that completely.) Jun 13, 2016 at 9:25
  • 4
    re: EFLAGS, sure most instructions write it, but few instructions read it. You already mentioned register renaming, which makes write-after-write dependencies on EFLAGS a non-issue. Of course, nothing's ever that simple with x86: some instructions leave some flags unmodified, so CPUs have to rename different parts of EFLAGS separately. P4 didn't do that, giving inc a dependency on the last instruction to modify flags. Even though P4 is dead, some optimization guides still suggest avoiding inc. Jun 13, 2016 at 9:33
  • 3
    Also, register renaming happens at issue time, when uops leave the in-order queues of the front-end and enter the out-of-order core. This is several stages after decode. More importantly, on CPUs with a uop cache and/or loop buffer, the same instruction can be issued/renamed many times after being decoded once. Your over-simplifications in this answer are a useful approximation to reality so you can get to the point about zero-extension breaking false dependencies without including all of Agner Fog's microarch PDF :P Jun 13, 2016 at 9:38
  • It is pretty unclear to me how any of this is relevant to architectural decisions that were made 17 years ago. Please post your own answer. Jun 13, 2016 at 9:52

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