# What's the easiest way to determine if a register's value is equal to zero or not?

I'm using x86 assembly with the Irvine library.

What's the easiest way to check if a register value is equal to zero or not?

I used cmp instruction but i'm searching for alternative way. This is my code using cmp instruction and the register is ebx

``````    cmp ebx,0
je equ1
mov ebx,0
jmp cont
equ1:
mov ebx,1
jmp cont
cont:
exit
``````

This "booleanizes" a value, producing a 0 or 1 like `int ebx = !!ebx` would in C.

• You are using at least 80386 instructions (`ebx` does not exist on 8086). Also the answer depends on the instructions ahead of this code, the presence of zero value may sort of "leak" by previous instructions, saving you one more at the test, otherwise common idiom is `test ebx,ebx` to set ZF. Then to turn ZF into 0/1 value in ebx is another story, where that `test` may be again not part of optimal solution. Make up your mind, whether you want to determine if register is zero, or if you want to set some register to 0/1 according to it. # `mov ebx,0` = `xor ebx,ebx` when you can destroy flags. Commented Dec 15, 2016 at 23:22
• To illustrate my point (of importance of details), let's say the last (flag AND ebx) modifying instruction ahead of this was `neg ebx`. Then `sbb ebx,ebx` will set `ebx` to -1 when `ebx` was equal to zero, and to 0 for non-zero values (further `neg ebx` will turn that into your original 0/1 way of working). Commented Dec 15, 2016 at 23:32
• didn't work with me. Commented Dec 15, 2016 at 23:40
• BTW I got that `sbb` after `neg` result the other way.. for zero it will keep zero, for non zero it will do -1 ... So to return your 0/1 then `inc ebx` would do. # "didn't work with me" me neither. (I have no idea what you are talking about) Commented Dec 15, 2016 at 23:44
• I could have sworn we had a duplicate of this question, but I haven't had any luck finding it. I do, however, find a bunch of questions that implicitly contain the answer to your question, e.g. stackoverflow.com/questions/147173/… and stackoverflow.com/questions/13064809/the-point-of-test-eax-eax. They're all about what `test` does when both operands are the same register—which is exactly what you want here. `test ebx, ebx` + `jz` Commented Dec 16, 2016 at 15:23

Probably the "easiest", or simplest, "not-caring about details" answer how to determine is:

``````    ; here ebx is some value, flags are set to anything
test   ebx,ebx   ; CF=0, ZF=0/1 according to ebx
jz     whereToJumpWhenZero
; "non-zero ebx" will go here

; a branch when value was not zero instead of "jz".
``````

There's a detailed answer from Peter Cordes to "`testl` eax against eax?" question reasoning about flags being set, etc. Also has a link to yet another similar answer, but reasoning about why it is best way from performance point of view. :)

How to set some other register (I will pick `eax`) to 1 when `ebx` is zero, and to 0 when `ebx` is non-zero (non destructive way for `ebx` itself):

``````    xor   eax,eax  ; eax = 0 (upper 24 bits needed to complete "al" later)
test  ebx,ebx  ; test ebx, if it is zero (ZF=0/1)
setz  al       ; al = 1/0 when ZF=1/0 (eax = 1/0 too)
``````

Or how to convert `ebx` itself into 1/0 when `ebx` is zero/non-zero:

``````    neg   ebx      ; ZF=1/0 for zero/non-zero, CF=not(ZF)
sbb   ebx,ebx  ; ebx = 0/-1 for CF=0/1
inc   ebx      ; 1 when ebx was 0 at start, 0 otherwise
``````

Or how to convert `ebx` itself into 1/0 when `ebx` is zero/non-zero, other variant (faster on "P6" to "Haswell" cores):

``````    test  ebx,ebx  ; ZF=1/0 for zero/non-zero ebx
setz  bl       ; bl = 1/0 by ZF (SETcc can target only 8b r/m)
movzx ebx,bl   ; ebx = bl extended to 32 bits by zeroes
``````

etc, etc... It depends what happens before your testing, and also what you really want as output of test, there're many possible ways (optimal for different situations, and optimal for different target CPU).

I will add few more extremely common situations... A counter-loop down-counting from N to zero, to loop N times:

``````    mov   ebx,5   ; loop 5 times
exampleLoop:
; ... doing something, preserving ebx
dec   ebx
jnz   exampleLoop ; loop 5 times till ebx is zero
``````

How to process 5 elements of `word` (16b) array (accessing them in array[0], array[1], ... order):

``````    mov   ebx,-5
lea   esi,[array+5*2]
exampleLoop:
mov   ax,[esi+ebx*2]  ; load value from array[i]
; process it ... and preserve esi and ebx
inc   ebx
jnz   exampleLoop  ; loop 5 times till ebx is zero
``````

One more example, I somehow like this one a lot:

How to set target register (`eax` in example) to ~0 (-1)/0 when `ebx` is zero/non-zero and you already have value `1` in some register (`ecx` in example):

``````    ; ecx = 1, ebx = some value
cmp   ebx,ecx  ; cmp ebx,1 => CF=1/0 for ebx zero/non-zero
sbb   eax,eax  ; eax = -1 (~0) / 0 for CF=1/0 ; ebx/ecx intact
``````

The -1 may look as practical as 1 (for indexing purposes at least), but -1 works also as full bitmask for further `and/xor/or` operations, so sometimes it is more handy.

• Thanks it works correctly :) i appreciate your help. Commented Dec 16, 2016 at 0:16
• For the same-register case without using any extra regs: `test ebx,ebx` / `setz bl` / `movzx ebx, bl` should be more efficient on P6 to Haswell (SBB is 2c latency / 2 uop). `neg/sbb/inc` is more efficient on Pentium4 (slow setcc), and I think they're equal on Broadwell and later, and on AMD (all 1c latency), and has smaller code-size (especially in 32-bit). Commented Dec 16, 2016 at 4:36
• test/setz/movzx is what gcc6.2 `-mtune=haswell` does if you give it a situation where it wants to do it in-place: godbolt.org/g/076BSI. Clang zeros a separate register and then uses a mov. Commented Dec 16, 2016 at 4:50
• @PeterCordes thanks, added to answer as another variant... plus put emphasis on "many" .. ;) :D ... (but practically, if anyone needs most optimal "set ebx to 1/0 when zero/non-zero", there's probably way to change the other part of algorithm to get better performance without that `ebx = ebx ? 0 : 1;` :)) .. except some similar curiosities as sgn(number) implementation, which has some good answer here on SO too, I think 1-2 months back you were after it :). Commented Dec 16, 2016 at 8:25
• Curiously, Intel's compiler virtually always uses `CMOV` instructions in situations like this, even when it seems to me that an alternate sequence of instructions (like those @Peter suggests) would be more optimal. So either the Intel engineers have special information that conditional moves are actually always better, or the optimizer is just written with this as a fixed path. (Or maybe this is one of the ways they stick it to AMD, since AMD processors tend to have slightly higher latencies for conditional moves.) Commented Dec 16, 2016 at 15:12

Use the flags, Luke
You test if a register is zero by checking the zero flag.
If the register obtained its value by some operation that affected the flags (or, more specifically, the zero flag) then you don't have to do anything, because the zero flag will already reflect the value stored in that register.

Test only if needed
If you cannot guarantee that the flags have been set, you'll have to use a test operation.
These operations come in two flavors: destructive and non-destructive.

You can see a list of instructions and the flags it alters at: http://ref.x86asm.net—more specifically, at: http://ref.x86asm.net/coder32-abc.html

The `mov` and `lea` instructions never alter flags and thus need assistance. Most other instructions set at least one flag.

Don't create false dependencies
If you need to test a register for zero, but don't want to alter its value, you use the `test` instruction.
You should not use a `or` or `and` instruction to check a register, because the CPU may not know that `or/and` can be used non-destructively and may not be able to apply certain optimizations. The technical term for this is a 'false dependency'. The register needs ebx and 'thinks' it was changed recently so it waits for the result to finalize.

``````test ebx, ebx  ; <-- CPU knows ebx was not altered, no stalls on subsequent reads.
or   ebx, ebx  ; <-- CPU 'thinks' ebx was changed, stall on subsequent read.
``````

If you want the zero state to reflect in another register, you can simply `mov` ebx to another register.

Reduce a value to a boolean
If you want to reduce the register to a boolean (True if non-zero, False otherwise), you use one of the following sequences:

``````; ebx holds the value to reduce to a boolean.
; eax is an unused register.
``````
``````xor eax, eax   ; eax = 0
sub eax, ebx   ; eax = 0 - ebx; CF (carry flag) = 1 if ebx <> 0
sbb ebx, ebx   ; ebx = ebx - ebx - CF
; <<-- ebx = -1 if non zero, 0 if zero
``````
``````xor eax, eax   ; eax = 0
sub eax, ebx   ; eax = - ebx; CF = 1 if ebx <> 0
adc ebx, eax   ; ebx = (ebx + -ebx) aka 0 + CF
; <<== ebx = 1 if non zero, 0 if zero
``````
``````test ebx, ebx  ; force ZF to be correct
setnz al       ; Store 1 if non-zero, 0 otherwise in byte register AL.
``````

Note that the use of byte registers can be problematic due to stalls related to "partial register writes".

• As Ped7g's answer points out, `neg ebx` sets flags from `0 - ebx` in one instruction (but also modifies the original value). Commented Dec 16, 2016 at 19:04

You could use:

``````or ebx, 0 ;This does nothing, just triggers the zero flag if ebx is zero
jnz notZero
or ebx, 1 ;ebx was zero, then ebx is 1
notZero:
``````
• Downvoting as you go straight for `or ebx,0`, even when I already posted in comment the common idiom is `test ebx,ebx`. You could have at least use `or ebx,ebx` to avoid `0` immediate, but the `test` is still better, as that one is widely used by C/C++ compilers, so CPU can have extra optimizations for that, while the `or` may be treated as ordinary arithmetic operation. Commented Dec 16, 2016 at 0:06
• Yeah, I saw your answer after I posted mine, learnt something! Thanks! Commented Dec 16, 2016 at 1:53
• @Ped7g: More about why `or` is a bad choice for this: stackoverflow.com/a/33724806/224132. Summary: Besides the obvious code-size, `test ebx,ebx` can macro-fuse with a JCC, and it doesn't write EBX, introducing an extra cycle of latency into the dependency chain for the next thing to read EBX. So yes, CPUs do "have extra optimizations" for TEST/JCC vs. OR/JCC, and the OR is just treated the same as any other OR. Commented Dec 16, 2016 at 4:30