Yes, there is a difference in performance.
The best choice for comparing a register with zero is
test reg, reg. It sets FLAGS the same way
cmp reg,0 would, and is at least as fast1 as any other way, with smaller code-size.
(Even better is when
ZF is already set appropriately by the instruction that set
reg so you can just branch, setcc, or cmovcc directly. For example, the bottom of a normal loop often looks like
dec ecx /
jnz .loop_top. Most x86 integer instructions "set flags according to the result", including ZF=1 if the output was
or reg,reg can't macro-fuse with a JCC into a single uop on any existing x86 CPUs, and adds latency for anything that later reads
reg because it rewrites the value into the register.
cmp's downside is usually just code-size.
Footnote 1: There is a possible exception, but only on obsolete P6-family CPUs (Intel up to Nehalem, replaced by Sandybridge-family in 2011). See below about avoiding register-read stalls by rewriting the same value into a register. Other microarchitecture families don't have such stalls, and there's never any upside to
The FLAGS results of
test reg,reg /
and reg,reg /
or reg,reg are
cmp reg, 0 in all cases (except for AF) because:
CF = OF = 0 because
and always do that, and for
cmp because subtracting zero can't overflow or carry.
PF set according to the result (i.e.
reg® for test, or
reg - 0 for cmp.
AF is undefined after
test, but set according to the result for
cmp. I'm ignoring it because it's really obscure: the only instructions that read AF are the ASCII-adjust packed-BCD instructions like
You can of course check conditions other than
reg == 0 (ZF), e.g. test for negative signed integers by looking at SF. But fun fact:
jl, the signed less-than condition, is more efficient than
js on some CPUs after a
cmp. They're equivalent after compare against zero because OF=0 so the
l condition (
SF!=OF) is equivalent to
Every CPU that can macro-fuse TEST/JL can also macro-fuse TEST/JS, even Core 2. But after
CMP byte [mem], 0, always use JL not JS to branch on the sign bit because Core 2 can't macro-fuse that. (At least in 32-bit mode; Core 2 can't macro-fuse at all in 64-bit mode).
The signed-compare conditions also let you do stuff like
jg, looking at ZF as well as SF!=OF.
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.
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).
Macro-fusion of test/jcc into a single uop in the decoders
The decoders in Intel and AMD CPUs can internally macro-fuse
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
sub) as well as
or is not one of them. AMD CPUs can only merge
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
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
AND is simpler, and probably uses slightly less power, but still can't run any faster than one clock cycle.
or reg, reg adds another cycle of latency to the dependency chain for following instructions that need to read the register. It's an
x |= x in the chain of operations that lead to the value you want.
You might think that extra register write would also need an extra physical register-file (PRF) entry vs.
test, but that's probably not the case. (See https://blog.stuffedcow.net/2013/05/measuring-rob-capacity/ for more about PRF capacity impact on out-of-order exec).
test has to produce its FLAGS output somewhere. On Intel Sandybridge-family CPUs at least, when an instruction produces a register and a FLAGS result, both of them are stored together in the same PRF entry. (Source: an Intel patent I think. This is from memory but seems like an obviously sane design.)
An instruction like
test that only produces a FLAGS result also needs a PRF entry for its output. Presumably this is slightly worse: the old physical register is still "alive", referenced as the holder of the value of the architectural register written by some older instruction. And now architectural EFLAGS (or more specifically, both the separate-renamed CF and SPAZO flag groups) point to this new physical register in the RAT (register allocation table) updated by the renamer. Of course, the next FLAGS-writing instruction will overwrite that, allowing that PR to be freed once all its readers have read it and executed. This is not something I think about when optimizing, and I don't think tends to matter in practice.
P6-family register-read stalls: possible upside to
P6-family CPUs (PPro / PII to Nehalem) have a limited number of register-read ports for the issue/rename stage to read "cold" values (not forwarded from an in-flight instruction) 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).
Re-writing a register with the same value on purpose to keep it "hot" can actually be an optimization for some cases of surrounding code, on P6. Early P6 family CPUs couldn't do macro-fusion at all, so you aren't even missing out on that by using
and reg,reg instead of
test. But Core 2 (in 32-bit mode) and Nehalem (in any mode) can macro-fuse test/jcc so you're missing out on that.
and is equivalent to
or for this purpose on P6-family, but less bad if your code ever runs on a Sandybridge-family CPU: it can macro-fuse
jcc but not
jcc. The extra cycle of latency in the dep-chain for the register is still a disadvantage on P6, especially if the critical path involving it is the main bottleneck.)
P6 family is very much obsolete these days (Sandybridge replaced it in 2011), and CPUs before Core 2 (Core, Pentium M, PIII, PII, PPro) are very obsolete and getting into retrocomputing territory, especially for anything where performance matters. You can ignore P6-family when optimizing unless you have a specific target machine in mind (e.g. if you have a crusty old Nehalem Xeon machine) or you're tuning a compiler's
-mtune=nehalem settings for the few users still left.
If you're tuning something to be fast on Core 2 / Nehalem, use
test unless profiling shows that register-read stalls are a big problem in a specific case, and using
and actually fixes it.
On earlier P6-family,
and reg,reg might be ok as your default code-gen choice when the value isn't part of a problematic loop-carried dep chain, but is read later. Or if it is, but there's also a specific register-read stall that you can fix with
If you only want to test the low 8 bits of a full register,
test al,al avoids writing a partial-register, which on P6-family is renamed separately from the full EAX/RAX.
or al,al is much worse if you later read EAX or AX: partial-register stall on P6-family.(Why doesn't GCC use partial registers?)
History of the unfortunate
or reg,reg idiom
or reg,reg idiom may have came from 8080
ORA A, as pointed out in a comment.
8080's instruction set doesn't have a
test instruction, so your choices for setting flags according to a value included
ORA A and
ANA A. (Notice that the
A register destination is baked in to the mnemonic for both those instructions, and there aren't instructions to OR into different registers: it's a 1-address machine except for
mov, while 8086 is a 2-address machine for most instructions.)
ORA A was the usual go-to way to do it, so presumably that habit carried over into 8086 assembly programming as people ported their asm sources. (Or used automatic tools; 8086 was intentionally designed for easy / automatic asm-source porting from 8080 code.)
This bad idiom continues to be blindly used by beginners, presumably taught by people who learned it back in the day and passed it on without thinking about the obvious critical path latency downside for out-of-order execution. (Or the other more subtle problems like no macro-fusion.)
Delphi's compiler reportedly uses
or eax,eax, which was maybe a reasonable choice at the time (before Core 2), assuming that register-read stalls were more important than lengthening the dep chain for whatever reads it next. IDK if that's true or they were just using the ancient idiom without thinking about it.
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. (See the P6 section above).
Value in memory: maybe use
cmp or load it into a reg.
To test a value in memory, you can
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
mov eax, [mem] /
test eax,eax or something. If not, either way is 2 front-end uops, but it's a tradeoff between code-size and back-end uop count.
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 mode will un-laminate after the uop-cache. Either way leading to 3 fused-domain uops for
cmp dword [rsi + rcx*4], 0 /
On i7-6700k Skylake (tested with perf events
mov reg, [mem] (or
test reg,reg / jnz 2 uops in both fused and unfused domains, regardless of addressing mode, or
movzx instead of mov. Nothing to micro-fuse; does macro-fuse.
cmp byte [rip+static_var], 0 +
jne. 3 fused, 3 unfused. (front and back ends). The RIP-relative + immediate combination prevents micro-fusion. It also doesn't macro-fuse. Smaller code-size but less efficient.
cmp byte [rsi + rdi], 0 (indexed addr mode) /
jne 3 fused, 3 unfused. Micro-fuses in the decoders, but un-laminates at issue/rename. Doesn't macro-fuse.
cmp byte [rdi + 16], 0 +
jne 2 fused, 3 unfused uops. Micro-fusion of cmp load+ALU did happen because of the simple addressing mode, but the immediate prevents macro-fusion. About as good as load + test + jnz: smaller code-size but 1 extra back-end uop.
If you have a
0 in a register (or a
1 if you want to compare a bool), you can
cmp [mem], reg /
jne for even fewer uops, as low as 1 fused-domain, 2 unfused. But RIP-relative addressing modes still don't macro-fuse.
Compilers tend to use load + test/jcc even when the value isn't used later.
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
~0 would be another way to write it.)