In the x86-64 Tour of Intel Manuals, I read

Perhaps the most surprising fact is that an instruction such as MOV EAX, EBX automatically zeroes upper 32 bits of RAX register.

The Intel documentation ( General-Purpose Registers in 64-Bit Mode in manual Basic Architecture) quoted at the same source tells us:

  • 64-bit operands generate a 64-bit result in the destination general-purpose register.
  • 32-bit operands generate a 32-bit result, zero-extended to a 64-bit result in the destination general-purpose register.
  • 8-bit and 16-bit operands generate an 8-bit or 16-bit result. The upper 56 bits or 48 bits (respectively) of the destination general-purpose register are not be modified by the operation. If the result of an 8-bit or 16-bit operation is intended for 64-bit address calculation, explicitly sign-extend the register to the full 64-bits.

In x86-32 and x86-64 assembly, 16 bit instructions such as

mov ax, bx

don't show this kind of "strange" behaviour that the upper word of eax is zeroed.

Thus: what is the reason why this behaviour was introduced? At a first glance it seems illogical (but the reason might be that I am used to the quirks of x86-32 assembly).


I'm not AMD or speaking for them, but I would have done it the same way. Because zeroing the high half doesn't create a dependency on the previous value, that the CPU would have to wait on. The register renaming mechanism would essentially be defeated if it wasn't done that way.

This way you can write fast code using 32-bit values in 64-bit mode without having to explicitly break dependencies all the time. Without this behaviour, every single 32-bit instruction in 64-bit mode would have to wait on something that happened before, even though that high part would almost never be used. (Making int 64-bit would waste cache footprint and memory bandwidth; x86-64 most efficiently supports 32 and 64-bit operand sizes)

The behaviour for 8 and 16-bit operand sizes is the strange one. The dependency madness is one of the reasons that 16-bit instructions are avoided now. x86-64 inherited this from 8086 for 8-bit and 386 for 16-bit, and decided to have 8 and 16-bit registers work the same way in 64-bit mode as they do in 32-bit mode.

See also Why doesn't GCC use partial registers? for practical details of how writes to 8 and 16-bit partial registers (and subsequent reads of the full register) are handled by real CPUs.

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    I don't think it's strange, I think they didn't want to break too much and kept the old behavior there. – Alexey Frunze Jun 24 '12 at 11:56
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    @Alex when they introduced 32bit mode, there was no old behaviour for the high part. There was no high part before.. Of course after that it couldn't be changed anymore. – harold Jun 24 '12 at 11:59
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    I was speaking about 16-bit operands, why the top bits don't get zeroed in that case. They don't in non-64-bit modes. And that's kept in 64-bit mode too. – Alexey Frunze Jun 24 '12 at 12:04
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    I interpreted your "The behaviour for 16bit instructions is the strange one" as "it's strange that zero-extension doesn't happen with 16-bit operands in 64-bit mode". Hence my comments about keeping it the same way in 64-bit mode for better compatibility. – Alexey Frunze Jun 24 '12 at 12:09
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    @Alex oh I see. Ok. I don't think it's strange from that perspective. Just from a "looking back, maybe it wasn't such a good idea"-perspective. Guess I should have been clearer :) – harold Jun 24 '12 at 12:12

It simply saves space in the instructions, and the instruction set. You can move small immediate values to a 64-bit register by using existing (32-bit) instructions.

It also saves you from having to encode 8 byte values for MOV RAX, 42, when MOV EAX, 42 can be reused.

This optimization is not as important for 8 and 16 bit ops (because they are smaller), and changing the rules there would also break old code.

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    If that's correct, wouldn't it have made more sense for it to sign-extend rather than 0 extend? – Damien_The_Unbeliever Jun 24 '12 at 11:54
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    Sign extension is slower, even in hardware. Zero extension can be done in parallel with whatever computation produces the lower half, but sign extension can't be done until (at least the sign of) the lower half has been computed. – Jerry Coffin Jun 24 '12 at 14:26
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    Another related trick is to use XOR EAX, EAX because XOR RAX, RAX would need an REX prefix. – Neil Oct 2 '13 at 9:12
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    @Nubok: Sure, they could have added an encoding of movzx / movsx that takes an immediate argument. Most of the time it's more convenient to have the upper bits zeroed, so you can use a value as an array index (because all regs have to be the same size in an effective address: [rsi + edx] isn't allowed). Of course avoiding false dependencies / partial-register stalls (the other answer) is another major reason. – Peter Cordes Dec 18 '15 at 2:51
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    and changing the rules there would also break old code. Old code can't run in 64-bit mode anyway (e.g. 1-byte inc/dec are REX prefixes); this is irrelevant. The reason for not cleaning up the warts of x86 is fewer differences between long mode and compat/legacy modes, so fewer instructions have to decode differently depending on mode. AMD didn't know AMD64 was going to catch on, and was unfortunately very conservative so it would take fewer transistors to support. Long-term, it would have been fine if compilers and humans had to remember which things work differently in 64-bit mode. – Peter Cordes Apr 28 '19 at 18:37

Without zero extending to 64 bits, it would mean an instruction reading from rax would have 2 dependencies for its rax operand (the instruction that writes to eax and the instruction that writes to rax before it), this means that 1) the ROB would have to have entries for multiple dependencies for a single operand, which means the ROB would require more logic and transistors and take up more space, and execution would be slower waiting on an unnecessary second dependency that might take ages to execute; or alternatively 2), which I'm guessing happens with the 16 bit instructions, the allocation stage probably stalls (i.e. if the RAT has an active allocation for an ax write and an eax read appears, it stalls until the ax write retires).

mov rdx, 1
mov rax, 6
imul rax, rdx
mov rbx, rax
mov eax, 7 //retires before add rax, 6
mov rdx, rax // has to wait for both imul rax, rdx and mov eax, 7 to finish before dispatch to the execution units, even though the higher order bits are identical anyway

The only benefit of not zero extending is ensuring the higher order bits of rax are included, for instance, if it originally contains 0xffffffffffffffff, the result would be 0xffffffff00000007, but there's very little reason for the ISA to make this guarantee at such an expense, and it's more likely that the benefit of zero extension would actually be required more, so it saves the extra line of code mov rax, 0. By guaranteeing it will always be zero extended to 64 bits, the compilers can work with this axiom in mind whilst in mov rdx, rax, rax only has to wait for its single dependency, meaning it can begin execution quicker and retire, freeing up execution units. Furthermore, it also allows for more efficient zero idioms like xor eax, eax to zero rax without requiring a REX byte.

  • Partial-flags on Skylake at least does work by having separate inputs for CF vs. any of SPAZO. (So cmovbe is 2 uops but cmovb is 1). But no CPU that does any partial-register renaming does it the way you suggest. Instead they insert a merging uop if a partial reg is renamed separately from the full reg (i.e. is "dirty"). See Why doesn't GCC use partial registers? and How exactly do partial registers on Haswell/Skylake perform? Writing AL seems to have a false dependency on RAX, and AH is inconsistent – Peter Cordes Mar 31 '20 at 19:24
  • P6-family CPUs either stalled for ~3 cycles to insert a merging uop (Core2 / Nehalem), or earlier P6-family (P-M, PIII, PII, PPro) just stall for (at least?) ~6 cycles. Perhaps that is like you suggested in 2, waiting for the full reg value to be available via writeback to the permanent/architectural register file. – Peter Cordes Mar 31 '20 at 19:29
  • @PeterCordes oh, I knew about merging uops at least for partial flag stalls. Makes sense, but I forgot how it works for a minute; it clicked once but I forgot to make notes – Lewis Kelsey Mar 31 '20 at 20:03
  • @PeterCordes microarchitecture.pdf: This gives a delay of 5 - 6 clocks. The reason is that a temporary register has been assigned to AL to make it independent of AH. The execution unit has to wait until the write to AL has retired before it is possible to combine the value from AL with the value of the rest of EAX I can't find an example of the 'merging uop' that would be used to solve this though, same for a partial flag stall – Lewis Kelsey Mar 31 '20 at 21:09
  • Right, early P6 just stalls until writeback. Core2 and Nehalem insert a merging uop after/before? only stalling the front-end for a shorter time. Sandybridge inserts merging uops without stalling. (But AH-merging has to issue in a cycle by itself, while AL merging can be part of a full group.) Haswell/SKL doesn't rename AL separately from RAX at all, so mov al, [mem] is a micro-fused load+ALU-merge, only renaming AH, and an AH-merging uop still issues alone. The partial-flag merging mechanisms in these CPUs vary, e.g. Core2/Nehalem still just stall for partial-flags, unlike partial-reg. – Peter Cordes Apr 1 '20 at 2:30

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