test eax, eax more efficient than
cmp eax, 0? Is there any case that the
test eax, eax is necessary where
cmp eax, 0 doesn't fulfill requirement?
As Zang MingJie has already said in a comment,
test eax,eax is almost identical to
cmp eax,0, except that it shorter than
cmp, because with
cmp you have to supply
0 as an argument. Note that the savings are not very large, because the 2nd operand gets sign-extended to match the size of the 1st operand, so it does not necessarily take a whole 4 bytes to represent that zero.
Now, what you are asking is whether there is any other difference. This is a reasonable question to ask, because
cmp is an arithmetic operation, (it performs a subtraction and discards the result,) while
test is a logical operation, (it performs a bitwise AND and discards the result,) so one could reasonably suspect that they may modify the
Flags register differently.
As it turns out, both instructions modify the
Flags register in an almost identical fashion. Both instructions modify the OF SF ZF AF PF and CF bits of the flags register. The
test instruction always clears OF and CF, but that's also what
cmp against zero does. The only other difference is that the
cmp instruction will properly set the obscure
AF flag, while the
test instruction leaves the contents of that flag undefined. But in the case of
cmp eax,0 the AF will always be cleared regardless of the value of
eax, so there is nothing that you can learn from a
cmp eax,0 that you would not learn from a
Therefore, I would conclude that there is no situation where
test eax,eax will give you something that
cmp eax,0 will not, nor vice versa. The two instructions appear to be completely interchangeable for any practical or even not-so-practical purpose, except for saving a byte or two of instruction code.
test eax,eax instead of
cmp eax,0 shows that you know your assembly. It also shows that you prefer a slightly cryptic, and marginally better performing instruction over a straightforward, understandable instruction. This is the kind of thing that tends to earn bonus points from other geeks, but it has not had any practical usefulness in the real world in the last couple of decades or so.
As stated above in comment and accepted answer also that these instructions are almost identical when used this way, but then why there are two instructions in the instruction set if they are same?
Because they're different if used with different operands.
The fact that
test same,same works as a compare against zero is just a convenient consequence of how 2's complement and FLAGS work, making it a useful peephole optimization.
TEST instruction uses AND logic on the bit pairs from both the arg0 and arg1 and can check if a specific bit is set or not, then FLAGS set accordingly. (With the integer result discarded). Just like
cmp sets FLAGS from a subtract while discarding the integer result.
TEMP ← SRC1 **AND** SRC2; SF ← MSB(TEMP); IF TEMP=0 THEN ZF ← 1; ELSE ZF ← 0; FI: PF ← BitwiseXNOR(TEMP[0:7]); CF ← 0; OF ← 0; (* AF is undefined *)
The OF and CF flags are set to 0. The SF, ZF, and PF flags are set according to the result (see the “Operation” section above). The state of the AF flag is undefined.
(The TEST operation sets the flags CF and OF to zero. The SF is set to the most significant bit of the result of the AND. If the result is 0, the ZF is set to 1, otherwise set to 0.)
While CMP instruction uses SUB instruction and subtract arg1 from arg0 and will set CF(Carry Flag) and ZF(Zero Flag) based on given args to CMP instruction, if both are equal(arg1==arg0) then it's obvious that the result will be zero and ZF will be set to 1 and if arg0 > arg1 then no flag will be set(remains 0 for ZF and CF) and if arg0 < arg1 then ZF will remain 0 as they are not equal but CF will be set.
temp ← SRC1 − SignExtend(SRC2); ModifyStatusFlags; (* Modify status flags in the same manner as the SUB instruction*)
The CF, OF, SF, ZF, AF, and PF flags are set according to the result.
Reference from: assembly_language_for_x86_processors.pdf