13

Is there any execution speed difference using the following code:

cmp al, 0
je done

and the following:

or al, al
jz done

I know that the JE and JZ instructions are the same, and also that using OR gives a size improvement of one byte. However, I am also concerned with code speed. It seems that logical operators will be faster than a SUB or a CMP, but I just wanted to make sure. This might be a trade-off between size and speed, or a win-win (of course the code will be more opaque).

  • 7
    The intel optimization manual says: Use a TEST of a register with itself instead of a CMP of the register to zero, this saves the need to encode the zero, so that's pretty much only the size. Macro-op fusion also applies to both. A quick glance into the Agner Fog tables suggests speed same for CMP and OR for most cpus. – Jester Nov 15 '15 at 15:19
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    @Jester: OR can't macro-fuse with anything. Older CPUs (Core2) can only macro-fuse signed-comparisons with test, but not cmp. AMD CPUs can only macro-fuse cmp and test, never an op that also writes a register. – Peter Cordes Nov 15 '15 at 20:45
10

It depends on the exact code sequence, which specific CPU it is, and other factors.

The main problem with or al, al, is that it "modifies" EAX, which means that a subsequent instruction that uses EAX in some way may stall until this instruction completes. Note that the conditional branch (jz) also depends on the instruction, but CPU manufacturers do a lot of work (branch prediction and speculative execution) to mitigate that. Also note that in theory it would be possible for a CPU manufacturer to design a CPU that recognises EAX isn't changed in this specific case, but there are hundreds of these special cases and the benefits of recognising most of them are too little.

The main problem with cmp al,0 is that it's slightly larger, which might mean slower instruction fetch/more cache pressure, and (if it is a loop) might mean that the code no longer fits in some CPU's "loop buffer".

As Jester pointed out in comments; test al,al avoids both problems - it's smaller than cmp al,0 and doesn't modify EAX.

Of course (depending on the specific sequence) the value in AL must've come from somewhere, and if it came from an instruction that set flags appropriately it might be possible to modify the code to avoid using another instruction to set flags again later.

  • The value in AL comes from a BIOS interrupt, so that doesn't qualify as 'setting flags appropriately'... iret would restore flags anyway. I also had in mind a print subroutine that used lodsb, and checked for a null terminator, does lodsb alter flags based on what is in AL? – sadljkfhalskdjfh Nov 15 '15 at 16:44
  • @AnonymousShadow In that context the performance of your comparison instruction is insignificant and you shouldn't worry about it. A BIOS interrupt will take hundreds of cycles at minimum, up to billions of cycles for a slow I/O operation. – Ross Ridge Nov 15 '15 at 22:27
  • @RossRidge what about using LODSB with a huge string? makes a difference size-wise anyway, might as well use it. – sadljkfhalskdjfh Nov 16 '15 at 0:08
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    @AnonymousShadow: Use lodsb if optimizing for code size. Otherwise, mov al, [esi] / inc esi decodes to only 2 uops instead of 3 on Intel CPUs (e.g. Haswell), so it potentially runs faster. Depending on your loop, you might be able to avoid the pointer increment with a more complex addressing mode (smaller code size, but 2-register addressing modes can't micro-fuse on Intel SnB-family). See my answer for why test is better for the same reason (fewer uops thanks to macro-fusion with a branch). If you're using setcc to consume the flags, rather than a branch, it's less important. – Peter Cordes Nov 18 '15 at 16:15
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    @Brendan Both test al,al and cmp al,0 occupy 2 bytes. It's only when you start using another register that the sizes differ. – Sep Roland Nov 22 '15 at 15:26
20

Yes, there is a difference in performance.

The best choice for comparing a register with zero on modern x86 is test reg, reg (if ZF isn't already set appropriately by the instruction that set reg). It's like AND reg,reg but without writing the destination.

or reg,reg can't macro-fuse, adds latency for anything that reads it later, and it needs a new physical register to hold the result. (So it uses up register-renaming resources where test wouldn't, limiting the CPU's out-of-order instruction window). (Rewriting the dst can be a win on Intel P6-family, though, see below.)


The flag results of test reg,reg / and reg,reg / or reg,reg are identical to cmp reg, 0 in all cases (except for AF):

  • CF = OF = 0 because test/and always do that, and for cmp because subtracting zero can't overflow or carry.
  • ZF, SF, PF set according to the result (i.e. reg): reg&reg for test, or reg - 0 for cmp. So you can test for negative signed integers or unsigned with the high bit set by looking at SF.

    Or with jl, because OF=0 so the l condition (SF!=OF) is equivalent to SF. Every CPU that can macro-fuse TEST/JL can also macro-fuse TEST/JS, even Core2. But after CMP byte [mem],0, always use JL not JS to branch on the sign bit.

(AF is undefined after test, but set according to the result for cmp. I'm ignoring it because it's really obscure: the only consumers for AF are the ASCII-adjust packed-BCD instructions like AAS, and lahf / pushf.)


test is shorter to encode than cmp with immediate 0, in all cases except the cmp al, imm8 special case which is still two bytes. Even then, test is preferable for macro-fusion reasons (with jle and similar on Core2), and because having no immediate at all can possibly help uop-cache density by leaving a slot that another instruction can borrow if it needs more space (SnB-family).


The decoders in Intel and AMD CPUs can internally macro-fuse test and cmp with some conditional branch instructions into a single compare-and-branch operation. This gives you a max throughput of 5 instructions per cycle when macro-fusion happens, vs. 4 without macro-fusion. (For Intel CPUs since Core2.)

Recent Intel CPUs can macro-fuse some instructions (like and and add/sub) as well as test and cmp, but or is not one of them. AMD CPUs can only merge test and cmp with a JCC. See x86_64 - Assembly - loop conditions and out of order, or just refer directly to Agner Fog's microarch docs for the details of which CPU can macro-fuse what. test can macro-fuse in some cases where cmp can't, e.g. with js.

Almost all simple ALU ops (bitwise boolean, add/sub, etc.) run in a single cycle. They all have the same "cost" in tracking them through the out-of-order execution pipeline. Intel and AMD spend the transistors to make fast execution units to add/sub/whatever in a single cycle. Yes, bitwise OR or AND is simpler, and probably uses less power, but still can't run any faster than one clock cycle.


Also, as Brendan points out, or reg, reg adds another cycle of latency to the dependency chain for following instructions that need to read the register.

However, on P6-family CPUs (PPro / PII to Nehalem), writing the destination register can actually be an advantage. There are a limited number of register-read ports for the issue/rename stage to read from the permanent register file, but recently-written values are available directly from the ROB. Rewriting a register unnecessarily can make it live in the forwarding network again to help avoid register-read stalls. (See Agner Fog's microarch pdf.

Delphi's compiler reportedly uses or eax,eax, which was a reasonable choice at the time, assuming that register-read stalls were more important than lengthening the dep chain for whatever reads it next.

Unfortunately, compiler-writers at the time didn't know the future, because and eax,eax performs exactly equivalently to or eax,eax on Intel P6-family, but is less bad on other uarches because and can macro-fuse on Sandybridge-family.

For Core2/Nehalem (the last 2 P6-family uarches), test can macro-fuse but and can't, so (unlike for Pentium II/III/M) it's a trade-off between macro-fusion and possibly reducing register-read stalls. The the register-read-stall avoidance does still come at the cost of extra latency if the value is read after being tested, so test can be a better choice than and in some cases even before a cmov or setcc, not a jcc, or on CPUs without macro-fusion.

If you're tuning something to be fast across multiple uarches, use test unless profiling shows that register-read stalls are a big problem in a specific case on Core2/Nehalem, and using and actually fixes it.

IDK where the or reg,reg idiom came from, except maybe that it's shorter to type. Or perhaps it was used on purpose for P6 CPUs to rewrite a register deliberately before using it some more. Coders at the time couldn't predict that it would end up being less efficient than and for that purpose. But obviously we should never use it over test or and in new code. (There's only a difference when it's immediately before a jcc on Sandybridge-family, but it's simpler to just forget about or reg,reg.)


To test a value in memory, it's fine to cmp dword [mem], 0, but Intel CPUs can't macro-fuse flag-setting instructions that have both an immediate and a memory operand. If you're going to use the value after the compare in one side of the branch, you should probably mov eax, [mem] / test eax,eax or something. If not (e.g. testing a boolean), cmp with a memory operand is fine.

Although note that some addressing modes won't micro-fuse either on SnB-family: RIP-relative + immediate won't micro-fuse in the decoders, or an indexed addressing modes will un-laminate. Either way leading to 3 fused-domain uops for cmp dword [rsi + rcx*4], 0 / jne or [rel some_static_location].

You could also test a value in memory with test dword [mem], -1, but don't. Since test r/m16/32/64, sign-extended-imm8 isn't available, it's worse code-size than cmp for anything larger than bytes. (I think the design idea was that if you you only want to test the low bit of a register, just test cl, 1 instead of test ecx, 1, and use cases like test ecx, 0xfffffff0 are rare enough that it wasn't worth spending an opcode. Especially since that decision was made for 8086 with 16-bit code, where it was only the difference between an imm8 and imm16, not imm32.)

I wrote -1 rather than 0xFFFFFFFF so it would be the same with byte or qword. ~0 would be another way to write it.

  • @Zboson: yup, thanks for catching the missing not – Peter Cordes Nov 18 '15 at 15:54
  • I usually think in terms of number of micro-ops instead of instructions. A folded instruction is really two operations with two micro-ops (that count as one micro-op). On Haswell I did six micro-ops (or operations)/clock cycle but five instructions/cycle. I don't know what the maximum micro-ops/clock cycle are possible but it's at least six. I guess I mean the number of operations /cycle is more interesting. I'm not really disagreeing with anything you wrote. – Z boson Nov 18 '15 at 15:57
  • @Zboson: I usually think in terms of fused-domain uops. I also consider execution ports when it's relevant, but if there are load/stores involved you're often limited by the frontend / pipeline width (4 uops / clock), not execution resources. (Assuming of course you're not limited by dep chains or cache misses.) I only pointed out instructions / clock as a way of explaining why getting macro-fusion to happen was important. – Peter Cordes Nov 18 '15 at 16:03
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    I think that the origins of OR AL,AL can be traced back to ORA A on the 8080. As the oldest part of the MSDOS API was modelled after that of CP/M to facilitate porting I can imagine lots of early DOS code was seriously influenced by code that started its existence on the 8080. – fvu Mar 29 '18 at 16:00
  • @fvu: Thanks! Yes, 8086 was specifically designed for easy asm source porting from 8080. I found this 8080 ISA ref and indeed, there's no TEST instruction, just ORA or ANA that are shorter than 2-byte CPI 0 to compare with an explicit immediate. Apparently most people picked OR instead of AND to set flags from A, probably because the mnemonic reads more easily. – Peter Cordes Mar 29 '18 at 16:32

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